predicting the sparticle spectrum from guts via susy threshold …3a10.1007%2fjhep07... ·...
TRANSCRIPT
JHEP07(2016)108
Published for SISSA by Springer
Received: December 22, 2015
Revised: June 23, 2016
Accepted: July 5, 2016
Published: July 21, 2016
Predicting the sparticle spectrum from GUTs via
SUSY threshold corrections with SusyTC
Stefan Antuscha,b and Constantin Slukaa
aDepartment of Physics, University of Basel,
Klingelbergstr. 82, CH-4056 Basel, SwitzerlandbMax-Planck-Institut fur Physik (Werner-Heisenberg-Institut),
Fohringer Ring 6, D-80805 Munchen, Germany
E-mail: [email protected], [email protected]
Abstract: Grand Unified Theories (GUTs) can feature predictions for the ratios of quark
and lepton Yukawa couplings at high energy, which can be tested with the increasingly
precise results for the fermion masses, given at low energies. To perform such tests, the
renormalization group (RG) running has to be performed with sufficient accuracy. In su-
persymmetric (SUSY) theories, the one-loop threshold corrections (TC) are of particular
importance and, since they affect the quark-lepton mass relations, link a given GUT flavour
model to the sparticle spectrum. To accurately study such predictions, we extend and gen-
eralize various formulas in the literature which are needed for a precision analysis of SUSY
flavour GUT models. We introduce the new software tool SusyTC, a major extension to
the Mathematica package REAP [1], where these formulas are implemented. SusyTC extends
the functionality of REAP by a full inclusion of the (complex) MSSM SUSY sector and a
careful calculation of the one-loop SUSY threshold corrections for the full down-type quark,
up-type quark and charged lepton Yukawa coupling matrices in the electroweak-unbroken
phase. Among other useful features, SusyTC calculates the one-loop corrected pole mass of
the charged (or the CP-odd) Higgs boson as well as provides output in SLHA conventions,
i.e. the necessary input for external software, e.g. for performing a two-loop Higgs mass
calculation. We apply SusyTC to study the predictions for the parameters of the CMSSM
(mSUGRA) SUSY scenario from the set of GUT scale Yukawa relations yeyd
= −12 ,
yµys
= 6,
and yτyb
= −32 , which has been proposed recently in the context of SUSY GUT flavour
models.
Keywords: Beyond Standard Model, GUT, Renormalization Group, Supersymmetric
Standard Model
ArXiv ePrint: 1512.06727
Open Access, c© The Authors.
Article funded by SCOAP3.doi:10.1007/JHEP07(2016)108
JHEP07(2016)108
Contents
1 Introduction 1
2 Predictions for Yukawa coupling ratios from GUTs 3
3 SUSY threshold corrections & numerical procedure 5
4 The REAP extension SusyTC 16
5 The sparticle spectrum predicted from CG factors 17
5.1 Comments and discussion 20
6 Summary and conclusion 22
A The β-functions in the seesaw type-I extension of the MSSM 23
A.1 One-loop β-functions 23
A.2 Two-loop β-functions 28
B Self-energies and one-loop tadpoles including inter-generational mixing 36
C SusyTC documentation 42
1 Introduction
Supersymmetric (SUSY) Grand Unified Theory (GUT) models of flavour are promising
candidates towards solving the open questions of the Standard Model (SM) of Particle
Physics. They embrace the unification of the SM gauge couplings, a dark matter candidate,
a solution to the gauge hierarchy problem and an explanation of the hierarchies of masses
and mixing angles in the flavour sector. Whether a flavour GUT model can successfully
explain the observations in the flavour sector, depends on the renormalization group (RG)
evolution of the Yukawa matrices from the GUT scale to lower energies. Furthermore,
it is known that tan β enhanced supersymmetric threshold corrections (see e.g. [2–6]) are
essential in the investigation of mass (or Yukawa coupling) ratios predicted at the GUT
scale. Interesting well-known GUT predictions in this context are b − τ and b − τ − t
unification (for early work see e.g. [7–10]) and yµ = 3ys [11].1 Other promising quark-
lepton mass relations at the GUT scale have been discussed in [12, 13], e.g. yτ = ±32yb,
yµ = 6ys or yµ = 92ys. Various aspects regarding the impact of such GUT relations for
phenomenology have been studied in the literature, see e.g. [14–31] for recent works.
1yi are the Yukawa couplings in the diagonal basis.
– 1 –
JHEP07(2016)108
With the discovery of the Higgs boson at the LHC [32, 33] and the possible discovery of
sparticles in the near future, the question whether a set of SUSY soft-breaking parameters
can be in agreement with both, specific SUSY threshold corrections as required for realizing
the flavour structure of a GUT model, and constraints from the Higgs boson mass and
results on the sparticle spectrum, gains importance. To accurately study this question, we
introduce the new software tool SusyTC, a major extension to the Mathematica package
REAP [1].
REAP, which is designed to run the SM and neutrino parameters in seesaw scenarios
with a proper treatment of the right-handed neutrino thresholds, is a convenient tool
for top-down analyses of flavour (GUT) models, with the advantage of a user-friendly
Wolfram Mathematica front-end. However, the SUSY sector is not included. In order to
take supersymmetric threshold corrections into account in the analyses, for example of the
A4 flavour GUT models in [34, 35], the following procedure was undertaken: first REAP
was used to run the Yukawa matrices in the MSSM from the GUT-scale to a user-defined
“SUSY”-scale. At this scale, the SUSY threshold corrections were incorporated as mere
model parameters, in a simplified treatment assuming, e.g., degenerate first and second
generation sparticle masses (cf. [36]), without specializing any details on the SUSY sector.
Finally, the Yukawa matrices, corrected by these tan β-enhanced thresholds, were taken
as input for a second run of REAP, evolving the parameters in the SM from the “SUSY”-
scale to the top-mass scale.2 Although this procedure is quite SUSY model-independent, it
only allows to study the constraints on the SUSY sector indirectly (i.e. via the introduced
additional parameters and with simplifying assumptions), and it is unclear whether an
explicit SUSY scenario with these assumptions and requirements can be realised.
The aim of this work is to make full use of the SUSY threshold corrections to gain
information on the SUSY model parameters from GUTs. Towards this goal we extend and
generalize various formulas in the literature which are needed for a precision analysis of
SUSY flavour GUT models and implement them in SusyTC. For example, SusyTC includes
the full (CP violating) MSSM SUSY sector, sparticle spectrum calculation, a careful cal-
culation of the one-loop SUSY threshold corrections for the full down-type quark, up-type
quark and charged lepton Yukawa coupling matrices in the electroweak-unbroken phase,
and automatically performs the matching of the MSSM to the SM, including DR to MS
conversion. Among other useful features, SusyTC calculates the one-loop corrected pole
mass of the charged (or the CP-odd) Higgs boson as well as provides output in SLHA
conventions, i.e. the necessary input for external software, e.g. for performing a two-loop
Higgs mass calculation.
SusyTC is specifically developed to perform top-down analyses of SUSY flavour GUT
models. This is a major difference to other well-known SUSY spectrum generators (e.g. [37–
41], see e.g. [42] for a comparison), which run experimental constraints from low energies to
high energies, apply GUT-scale boundary conditions, run back to low energies and repeat
this procedure iteratively. SusyTC instead starts directly from the GUT-scale, allowing the
2Such a treatment of threshold corrections as additional model parameters is now implemented in the
latest version of RGEMSSM0N.m of REAP 11.1.2.
– 2 –
JHEP07(2016)108
user to define general (complex) Yukawa, trilinear, and soft-breaking matrices, as well as
non-universal gaugino masses, as input. These parameters are then run to low energies,
thereby enabling an investigation whether the GUT-scale Yukawa matrix structures of a
given SUSY flavour GUT model are in agreement with experimental data.
We apply SusyTC to study the predictions for the parameters of the Constrained MSSM
(mSUGRA) SUSY scenario from the GUT-scale Yukawa relations yeyd
= −12 ,
yµys
= 6,
and yτyb
= −32 , which have been proposed recently in the context of SUSY GUT flavour
models. With a Markov Chain Monte Carlo analysis we find a “best-fit” benchmark point
as well as the 1σ ranges for the sparticle masses and the correlations between the SUSY
parameters. Without applying any constraints from LHC SUSY searches or dark matter, we
find that the considered GUT scenario predicts a CMSSM sparticle spectrum above past
LHC sensitivities, but within reach of the current LHC run or a future high-luminosity
upgrade. Furthermore, the scenario generically features a bino-like neutralino LSP and a
stop NLSP with a mass that can be close to the present bounds.
This paper is organized as follows: in section 2 we review GUT predictions for Yukawa
coupling ratios. In section 3, we describe the numerical procedure in SusyTC and present
the main used formulas. We give a short introduction to the new features SusyTC adds to
REAP in section 4. In section 5 we study the predictions for the parameters of the CMSSM
SUSY scenario from the above mentioned GUT-scale Yukawa relations with SusyTC. In the
appendices we present other relevant formulas and a detailed documentation of SusyTC.
2 Predictions for Yukawa coupling ratios from GUTs
GUTs not only contain a unification of the SM forces, they also unify fermions into joint
representations. After the GUT gauge group is broken to the SM gauge group, this can lead
to predictions for the ratios of down-type quark and charged lepton Yukawa couplings which
result from group theoretical Clebsch Gordan (CG) factors. To confront such predictions
of GUT models with the experimental data, the RG evolution of the Yukawa couplings
from high to low energies has to be performed, including (SUSY) threshold corrections.
In SU(5) GUTs, for example, the right-handed down-type quarks and the lepton
doublets are unified in five-dimensional representations of SU(5) and the quark doublets
plus right-handed up-type quarks and right-handed charged leptons are unified in a ten-
dimensional SU(5) representation. The Higgs doublets are supplemented by SU(3)c triplets
and embedded into five-dimensional representations of SU(5). Using only these fields and a
single renormalizable operator to generate the Yukawa couplings for the down-type quarks
and charged leptons, so-called minimal SU(5) predicts Ye = Y Td for the Yukawa matri-
ces at the GUT scale. To correct this experimentally challenged scenario, SU(5) GUT
flavour models often introduce a 45-dimensional Higgs representation, which can lead to
the Georgi-Jarlskog relations yµ = −3ys and ye = 13yd [11].
It was pointed out in [12] (see also [13]) that other promising Yukawa coupling GUT
ratios can emerge in SU(5), e.g. yτ = ±32yb, yµ = 6ys or yµ = 9
2ys, and ye = −12yd from
higher dimensional GUT operators containing for instance a GUT breaking 24-dimensional
Higgs representation. A convenient test whether GUT predictions for the first two families
– 3 –
JHEP07(2016)108
can be consistent with the experimental data is provided by the — RG invariant and SUSY
threshold correction invariant3 — double ratio [36]
∣∣∣∣yµys ydye∣∣∣∣ = 10.7+1.8
−0.8 . (2.1)
While the Georgi-Jarlskog relations [11] imply a double ratio of 9, disfavoured by more
than 2σ, other combinations of CG factors [12, 13], e.g. yµ = 6ys and ye = −12yd can be in
better agreement (here with a double ratio of 12, within the 1σ experimental range).
The combination of GUT-scale Yukawa relations ye = −12yd, yµ = 6ys, and yτ = −3
2yb(as direct result of CG factors, cf. table 1 and figure 1, or as approximate relation after
diagonalization of the GUT-scale Yukawa matrices Yd and Ye) has been used to construct
SU(5) SUSY GUT flavour models in refs. [34, 35, 43, 44]. A subset of these relation,
yµ = 6ys, and yτ = −32yb, has been used in [45]. In addition to providing viable quark and
charged lepton masses, the GUT CG factors (Ye)ji/(Yd)ij = −12 and 6 can also be applied
to realize the promising relation between the lepton mixing angle θPMNS13 and the Cabibbo
angle, θPMNS13 ' θC sin θPMNS
23 , in flavour models, as discussed in [46].
As mentioned above, in supersymmetric GUT models the SUSY threshold corrections
can have an important influence on the Yukawa coupling ratios. When the MSSM is
matched to the SM, integrating out the sparticles at loop-level leads to the emergence of
effective operators, which can contribute sizeably to the Yukawa couplings, depending on
the values of the sparticle masses, tan β, and the soft-breaking trilinear couplings. Thereby,
via the SUSY threshold corrections, a given set of GUT predictions for the ratios yτyb
,yµys
and yeyd
imposes important constraints on the SUSY spectrum.
The SUSY threshold corrections can be subdivided into three classes: while at tree-
level the down-type quarks only couple to the Higgs field Hd, via exchange of sparticles
at one-loop level they can also couple to Hu, as shown in figure 2 in section 3. When the
sparticles are integrated out the emerging effective operator is enhanced for large tan β
(i.e. “tan β-enhanced”). Analogously, there are also tan β-enhanced threshold corrections
to the charged lepton Yukawa couplings. For Yu, however, the threshold effects emerging
from effective couplings to Hd are tanβ-suppressed. The second class of threshold correc-
tions emerges from the supersymmetric loops shown in figure 3. While some of them are
strongly suppressed, others lead to the emergence of effective operators proportional to the
soft SUSY-breaking trilinear couplings. For large trilinear couplings, they too can become
important. Finally there are threshold corrections from exchange of heavy Higgs doublets
and canonical normalization of external fields (i.e. from wavefunction renormalization di-
agrams), as shown in figures 4 and 5–7, respectively. Given the importance of the SUSY
threshold corrections, we will discuss them and their implementation in SusyTC in detail
in the next section.
3The invariance under SUSY threhold corrections holds under some generic conditions, cf. [36].
– 4 –
JHEP07(2016)108
AB C D R (Ye)ji/(Yd)ij
H24 F T H45 45 −12
H24 F T H5 5 −32
H24 T F H5 10 6
Table 1. Examples for dimension 5 effective operators (AB)R(CD)R and CG factors emerging
from the supergraphs of figure 1 when R and R are integrated out [12].
A
B
C
D
R R
Figure 1. Supergraphs corresponding to the operators of table 1 generating effectively Yukawa
couplings when the pair of messengers fields R and R is integrated out.
3 SUSY threshold corrections & numerical procedure
We follow the notation of REAP [1] (see also [47]) and use a RL convention for the Yukawa
matrices. The MSSM superpotential extended by a type-I seesaw mechanism [48–54] is
thus given by
WMSSM = YeijEciHd · Lj + YνijN
ciHu · Lj
+ YdijDciHd ·Qj − YuijU ciHu ·Qj +
1
2MnijN
ciN
cj + µHu ·Hd , (3.1)
where the left-chiral superfields Φc contain the charge conjugated fields ψ† and φ∗R. We use
the totally antisymmetric SU(2) tensor ε12 = −ε21 = 1 for the product Φ · Ψ ≡ εabΦaΨb.
The soft-breaking Lagrangian is given by
−Lsoft = −1
2Maλ
aλa + h.c.
+ Teij e∗RiHd · Lj + Tνij ν
∗RiHu · Lj + Tdij d
∗RiHd · Qj − Tuij u∗RiHu · Qj + h.c.
+ Q†im2QijQj+L
†im
2LijLj+u
∗Rim
2uij uRj+d∗Rim
2dijdRj+e∗Rim
2eij eRj+ν∗Rim
2νij νRj
+m2Hu |Hu|2 +m2
Hd|Hd|2 + (m2
3Hu ·Hd + h.c.) . (3.2)
Note that these conventions differ from SUSY Les Houches Accord 2 [55]. They can easily
be translated by
REAP & SusyTC Yu Yd Ye Tu Td Te m2u m2
dm2e
SLHA 2 Y Tu Y T
d Y Te T Tu T Td T Te (m2
u)T (m2d)T (m2
e)T
Since REAP includes the RG running in the type-I seesaw extension of the MSSM (with
the DR two-loop β-functions for the MSSM parameters and the neutrino mass opera-
tor given in [47]), we have calculated the DR two-loop β-functions of the gaugino mass
– 5 –
JHEP07(2016)108
parameters Ma, the trilinear couplings Tf , the sfermion squared mass matrices m2f, and
soft-breaking Higgs mass parameters m2Hu
and m2Hd
in the presence of Yν , Mn and m2ν
(using the general formulas of [56]). We list these β-functions in appendix A.
The Yukawa matrices and soft-breaking parameters are evolved to the SUSY scale
Q =√mt1
mt2, (3.3)
where the stop masses are defined by the up-type squark mass eigenstates ui with the
largest mixing to t1 and t2.4 REAP automatically integrates out the right-handed neutrinos,
as described in [1]. We assume that Mn is much larger than the SUSY scale Q. REAP
also features the possibility to add one-loop right-handed neutrino thresholds for the SM
parameters, following [57].
At the SUSY scale Q the tree-level sparticle masses and mixings are calculated. Con-
sidering heavy sparticles and large Q & TeV the SUSY threshold corrections are calculated
in the electroweak (EW) unbroken phase. In the EW unbroken phase there are in total
twelve types of loop diagrams contributing to the SUSY threshold corrections for Yd (cf.
figures 2 and 3).
The SUSY threshold corrections to Yd are calculated in the basis of diagonal squark
masses and are given by (in terms of DR quantities)
Y SMd = PdY
′dP
TQPh , (3.4)
where Pd, PQ, and Ph are the threshold corrections (3.12), (3.19), (3.20), and (3.22) due
to canonical normalization. Y ′dij is given by
Y ′dij = Y MSSMdij
cosβ
(1 +
1
16π2tanβ
(ηGij + ηWij + ηBij + ηTij
)+
1
16π2(εWij + εBij + εTij + εHij
))+ TMSSM
dijcosβ
1
16π2
(ζGij + ζBij
), (3.5)
where
ηGij = −8
3g2
3
µ∗
M3H2
(m2di
|M3|2,m2Qj
|M3|2
),
ηWij =3
2g2
2
M∗2µH2
(M2
2
|µ|2 ,m2Qj
|µ|2
),
ηBij =3
5g2
1
(1
9
µ∗
M1H2
(m2di
|M1|2,m2Qj
|M1|2
)+
1
3
M∗1µH2
(m2di
|µ|2 ,|M1|2|µ|2
)+
1
6
M∗1µH2
(|M1|2|µ|2 ,
m2Qj
|µ|2
)),
ηTij = − 1
µYdij
∑n,m
Ydim T†umn YunjH2
(m2un
|µ|2 ,m2Qm
|µ|2
), (3.6)
4SusyTC can also be set to use the convention Q =√mu1mu6 or a user-defined SUSY scale, as described
in appendix C.
– 6 –
JHEP07(2016)108
correspond to the tan β-enhanced loops of figure 2, and
εWij = 12g22C00
(|µ|2Q2
,|M2|2|µ|2 ,
m2Qj
|µ|2
),
εBij =3
5g21
(4
3C00
(|µ|2Q2
,|M1|2|µ|2 ,
m2di
|µ|2
)+
2
3C00
(|µ|2Q2
,|M1|2|µ|2 ,
m2Qj
|µ|2
)),
εTij =1
Ydij
∑n,m
Ydim Y†umn YunjH2
(m2un
|µ|2 ,m2Qm
|µ|2
),
εHij =2 sin2 β
Ydij
∑n,m
Ydim Y†umn YunjB1
(m2H
Q2
),
ζGij =8
3g23
1
M3H2
(m2di
|M3|2,m2Qj
|M3|2
),
ζBij = −3
5g21
1
9
1
M1H2
(m2di
|M1|2,m2Qj
|M1|2
), (3.7)
correspond to the loops in figures 3 and 4, respectively, where the contributions ζGij and
ζBij can become important in cases of small tan β and large trilinear couplings. The loop
functions H2, C00, and B1 are defined as
H2(x, y) ≡ x log(x)
(1− x)(x− y)+
y log(y)
(1− y)(y − x), (3.8)
C00(q, x, y) ≡1
4
(3
2− log(q) +
x2 log(x)
(1− x)(x− y)+
y2 log(y)
(1− y)(y − x)
), (3.9)
B1(q) ≡−3
4+
1
2log q . (3.10)
Y , T are the Yukawa- and trilinear coupling matrices rotated into the basis where the
squark mass matrices are diagonal, using the transformations
Yu = WuYuW†Q,
Tu = WuTuW†Q,
m2Q
= WQm2 diag
QW †Q,
m2u = Wum
2 diagu W †u , (3.11)
and analogously for down-type (s)quarks and charged (s)leptons.
The threshold correction Ph due to canonical normalization of external Higgs doublets
is given by
Ph =
√(UKhU †)−111 (3.12)
with U defined by(ha
Ha
)≡ U
(−εabHa
d∗
Hau
)=
(cosβ sinβ
− sinβ cosβ
)(−εabHa
d∗
Hau
), (3.13)
– 7 –
JHEP07(2016)108
Qi d†j
H∗u
g
Qid∗Rj
Qi d†j
H∗u
Hu Hd
u∗Rn Qm
Qi d†jQi
H∗u
BHu
Hd
Qi d†jd∗Rj
H∗u
BHu
Hd
Qi d†jQi
H∗u
WHu
Hd
Qi d†j
H∗u
B
Qid∗Rj
Figure 2. tanβ-enhanced SUSY threshold corrections to Yd.
where h and H are the mass eigenstates doublets of the MSSM Higgs scalar fields and
Kh ≡(
1
1
)+
1
16π2
(X11 + Y11 + Y11 +A11 +B11 X12 + Z12 + Z12 +A12 +B12
X∗12 + Z∗12 + Z∗12 +A∗12 +B∗12 X22 + Y22 + X22 +A11 +B11
),
(3.14)
with
X11 =∑i,j
|µ|2|Yuij |2B2
(m2ui ,m
2Qj
),
Y11 =∑i,j
|Tdij |2B2
(m2di,m2
Qj
),
Y11 =∑i,j
|Teij |2B2
(m2ei ,m
2Lj
),
X12 =∑i,j
−µTuij Y ∗uijB2
(m2ui ,m
2Qj
),
Z12 =∑i,j
−µTdij Y ∗dijB2
(m2di,m2
Qj
),
Z12 =∑i,j
−µTeij Y ∗eijB2
(m2ei ,m
2Lj
),
– 8 –
JHEP07(2016)108
Qi d†j
Hd
g
Qid∗Rj
Qi d†j
Hd
Hu Hd
u∗Rn Qm
Qi d†jQi
Hd
B Hd
Qi d†jd∗Rj
Hd
BHd
Qi d†jQi
Hd
W Hd
Qi d†j
Hd
B
Qid∗Rj
Figure 3. None tanβ-enhanced SUSY threshold corrections to Yd.
Qi d†j
H∗u
H
u†n Qm
Figure 4. Additional diagram with heavy Higgs doublet exchanged.
X22 =∑i,j
|µ|2|Ydij |2B2
(m2di,m2
Qj
),
X22 =∑i,j
|µ|2|Yeij |2B2
(m2ei ,m
2Lj
),
Y22 =∑i,j
|Tuij |2B2
(m2ui ,m
2Qj
),
A11 =3
5g21
1
12 (|µ|2 − |M1|2)3B2
(Q2, |M1|2, |µ|2
), (3.15)
– 9 –
JHEP07(2016)108
B11 = g221
4 (|µ|2 − |M2|2)3B2
(Q2, |M2|2, |µ|2
),
A12 =3
5g21µ∗M∗1B2
(|µ|2, |M1|2
),
B12 = g223µ∗M∗2B2
(|µ|2, |M2|2
), (3.16)
which correspond to the loops shown in figures 5 and 6. The loop functions B2 and B2 are
given by
B2 (x, y) ≡ x2 − y22 (x− y)3
+x y
(x− y)3log
(x
y
), (3.17)
B2 (q, x, y) ≡ 5(x3−y3
)+27x y (y−x)+6y2 (y−3x) log
(yx
)+6 (y−x)3 log
(x
q
)(3.18)
The threshold corrections Pf due to canonical normalization of the external fermion
fields are given by
Pf ≡√(Kdiagf
)−1Uf with Kdiag
f = UfKfU †f . (3.19)
For the threshold corrections of the down-type Yukawa matrix the Kf are given by
KQij = δij +1
16π2
((ρ3 + ρ2 + ρ1) δij + ρdij + ρdij + ρuij + ρuij
), (3.20)
with
ρ3 =8
3g23B3
(Q2, |M3|2,m2
Qj
),
ρ2 =3
2g22B3
(Q2, |M2|2,m2
Qj
),
ρ1 =1
18
3
5g21B3
(Q2, |M1|2,m2
Qj
),
ρdij =∑k
Y †djk YdkiB3
(Q2, |µ|2,m2
dk
),
ρdij =∑k
Y †djk YdkiB1
(m2H
Q2
)sin2 β ,
ρuij =∑k
Y †ujk YukiB3
(Q2, |µ|2,m2
uk
),
ρuij =∑k
Y †ujk YukiB1
(m2H
Q2
)cos2 β , (3.21)
corresponding to the loops in figure 7, and
Kdij = δij +1
16π2
((χ3 + χ1) δij + χdij + χdij
), (3.22)
– 10 –
JHEP07(2016)108
Hd H∗d
u∗Rj
Qi
Hd Hu
u∗Rj
Qi
Hd H∗d
d∗Rj
Qi
Hd Hu
d∗Rj
Qi
Hu H∗u
d∗Rj
Qi
Hu H∗u
u∗Rj
Qi
Hd H∗d
e∗Rj
Li
Hd Hu
e∗Rj
Li
Hu H∗u
e∗Rj
Li
Figure 5. Scalar loops contributing to threshold corrections from canonical normalization of
external Higgs fields.
– 11 –
JHEP07(2016)108
Hd H∗d
Hd
B
Hd H∗d
Hd
W
Hd Hu
Hd
B
Hu
Hd Hu
Hd
W
Hu
Hu H∗u
Hu
B
Hu H∗u
Hu
W
Figure 6. Fermion loops contributing to threshold corrections from canonical normalization of
external Higgs fields.
with
χ3 =8
3g23
(Q2, |M3|2,m2
dj
),
χ1 =2
9
3
5g21
(Q2, |M1|2,m2
dj
),
χdij =∑k
2 Ydik Y†dkjB3
(Q2, |µ|2,m2
Qk
),
χdij =∑k
2 Ydik Y†dkjB1
(m2H
Q2
)sin2 β . (3.23)
The diagrams for Kd are similar to the ones for KQ, when Q is replaced with d, with the
exception of the wino loop, which does not exist for external right-handed fermions. The
loop-functions B1 and B3 are given by
B1 (q) ≡ −1
4+
1
2log (q) , (3.24)
B3 (q, x, y) ≡ −1
4− x
2 (x− y)+
x2
2 (x− y)2log
(x
y
)+
1
2log
(y
q
). (3.25)
– 12 –
JHEP07(2016)108
Qi Q†j
u∗Rk
Hu
Qi Q†j
d∗Rk
Hd
Qi Q†j
u†k
H
Qi Q†j
d†k
H
Qi Q†i
g
Qi
Qi Q†i
W
Qi
Qi Q†i
B
Qi
Figure 7. Loops contributing to threshold corrections from canonical normalization of external
quark doublets.
For the charged leptons, Y SMe is given by
Y SMe = PeY
′eP
TL Ph , (3.26)
where Pe and PL are threshold corrections due to canonical normalization of external
charged lepton fields and
Y ′eij = Y MSSMeij cosβ
(1 +
1
16π2tanβ
(τWij + τBij
)+
1
16π2(δWij + δBij
))+ TMSSM
eij cosβ1
16π2ξBij , (3.27)
– 13 –
JHEP07(2016)108
with the tan β-enhanced contributions
τWij =3
2g2
2
M∗2µH2
(|M2|2|µ|2 ,
m2Lj
|µ|2
), (3.28)
τBij =3
5g2
1
(− µ∗
M1H2
(m2ei
|M1|2,m2Lj
|M1|2
)+M∗1µH2
(m2ei
|µ|2 ,|M1|2|µ|2
)− 1
2
M∗1µH2
(|M1|2|µ|2 ,
m2Lj
|µ|2
)),
and
δWij = 12g22C00
(|µ|2Q2
,|M2|2|µ|2 ,
m2Lj
|µ|2
),
δBij =3
5g21
(−2C00
(|µ|2Q2
,|M1|2|µ|2 ,
m2Lj
|µ|2
)+ 4C00
(|µ|2Q2
,|M1|2|µ|2 ,
m2ei
|µ|2
)),
ξBij =3
5g21
1
M1H2
(m2ei
|M1|2,m2Lj
|M1|2
). (3.29)
The diagrams for the Ye SUSY threshold corrections are analogous to the ones in figures 2
and 3, with the exception that the loop diagrams shown in the top rows do not exist.
The diagram of figure 4 also doesn’t have an analogue for Ye. Pe and PL are calculated
from (3.19) with
KL = δij +1
16π2((ρ2 + ρ1) δij + ρeij + ρeij
), (3.30)
where
ρ2 =3
2g22B3
(Q2, |M2|2,m2
Lj
),
ρ1 =1
2
3
5g21B3
(Q2, |M1|2,m2
Lj
),
ρeij =∑k
Y †ejk YekiB3
(Q2, |µ|2,m2
ek
),
ρeij =∑k
Y †ejk YekiB1
(m2H
Q2
)sin2 β , (3.31)
and
Ke = δij +1
16π2(χ1δij + χeij + χeij
), (3.32)
with
χ1 = 23
5g21B3
(Q2, |M1|2,m2
ei
),
χeij =∑k
2 Yeik Y†ekjB3
(Q2, |µ|2,m2
Lk
),
χeij =∑k
2Yeik Y†ekjB1
(m2H
Q2
)sin2 β . (3.33)
– 14 –
JHEP07(2016)108
Again, the loop diagrams for KL and Ke can be easily obtained from the diagrams for KQby suitable exchange of labels and indices and dropping non-existent gaugino loops.
Turning to Yu, the types of diagrams which were tan β-enhanced for Yd and Ye are now
tanβ-suppressed. However, there also exist SUSY threshold corrections which are indepen-
dent of tan β and enhanced by large trilinear couplings. These SUSY threshold corrections
to Yu can have important effects. For example the SUSY threshold corrections to the top
Yukawa coupling yt can be of significance in analyses of the Higgs mass and vacuum sta-
bility. The expression for the Yu SUSY threshold corrections can be readily obtained from
the SUSY threshold corrections to Yd (3.4)–(3.7) and (3.19)–(3.23) by the replacement5
d→ u ,
cosβ → sinβ , (3.34)
with the exception of the bino-loops, whose contribution become
ηBij =3
5g2
1
(−2
9
µ∗
M1H2
(m2di
|M1|2,m2Qj
|M1|2
)+
2
3
M∗1µH2
(m2ui
|µ|2 ,|M1|2|µ|2
)− 1
6
M∗1µH2
(|M1|2|µ|2 ,
m2Qj
|µ|2
)),
εBij =3
5g2
1
(8
3C00
( |µ|2Q2
,|M1|2|µ|2 ,
m2ui
|µ|2)− 2
3C00
(|µ|2Q2
,|M1|2|µ|2 ,
m2Qj
|µ|2
)),
ζBij =3
5g2
1
2
9
1
M1H2
(m2ui
|M1|2,m2Qj
|M1|2
),
χ1 =8
9
3
5g2
1
(Q2, |M1|2,m2
ui
), (3.35)
due to the different U(1) hypercharges of the (s)particles in the loop. The loop diagrams
are identical to the ones of figures 2, 3, and 4 with u and d exchanged.
After the SUSY threshold corrections are incorporated in the DR scheme, REAP converts
the Yukawa and gauge couplings to the MS scheme following [58].
Finally SusyTC calculates the value of |µ| and m3 from m2Hu
, m2Hd
, tanβ and MZ
by requiring the existence of spontaneously broken EW vacuum, which is equivalent to
vanishing one-loop corrected tad-pole equations of Hu and Hd
µ = eiφµ√
1
2
(tan(2β)
(m2Hu
tanβ − m2Hd
cotβ)−M2
Z −Re(ΠTZZ
(M2Z
))), (3.36)
with m2Hu≡ m2
Hu−tu and m2
Hd≡ m2
Hd−td. In the real (CP conserving) MSSM the phase φµ
is restricted to 0 and π. The expressions for the one-loop tadpoles tu, td and the transverse
Z-boson self energy ΠTZZ are based on [59], but extended to include inter-generational
mixing, and are presented in appendix B. Because µ enters the one-loop formulas for
the threshold corrections, treating tu, td and ΠTZZ as functions of tree-level parameters is
sufficiently accurate. The one-loop expression of the soft-breaking mass m3 is calculated as
m3 =
√1
2
(tan(2β)
(m2Hu− m2
Hd
)−(M2Z +Re
(ΠTZZ
(M2Z
)))sin(2β)
). (3.37)
5Note that (3.12)–(3.15) stay invariant.
– 15 –
JHEP07(2016)108
If desired, SusyTC allows to outsource a two-loop Higgs mass calculation to external
software, e.g. FeynHiggs [60–67], by calculating the pole mass mH+ (mA) as input for the
complex (real) MSSM
m2H+ =
1
cos(2β)
(m2Hu − m2
Hd−M2
Z −Re(ΠTZZ
(M2Z
))+ M2
W
−Re (ΠH+H− (mH+)) + td sin2 β + tu cos2 β
), (3.38)
m2A =
1
cos(2β)
(m2Hu − m2
Hd−M2
Z −Re(ΠTZZ
(M2Z
))×Re (ΠAA (mA)) + td sin2 β + tu cos2 β
), (3.39)
where MW is the DR W-boson mass given as
M2W (Q) = M2
W +Re(ΠTWW
(M2W
))= g2
v(Q)
2, (3.40)
with MZ and MW pole masses and the DR vacuum expectation value v(Q) given by
v2(Q) = 4M2Z +Re
(ΠTZZ
(M2Z
))35g
21(Q) + g22(Q)
. (3.41)
As in the previous formulas, the self energies ΠH+H− and ΠAA are based on [59], but
extended to include inter-generational mixing, and are understood as functions of tree-
level parameters. They are given in appendix B.
4 The REAP extension SusyTC
In this section we provide a “Getting Started” calculation for SusyTC. A full documentation
of all features is included in appendix C. Since SusyTC is an extension to REAP, an up-to-
date version of REAP-MPT [1] (available at http://reapmpt.hepforge.org) needs to be in-
stalled on your system. SusyTC consists out of the REAP model file RGEMSSMsoftbroken.m,
which is based on the model file RGEMSSM.m of REAP 1.11.2 and additionally contains,
among other things, the RGEs of the MSSM soft-breaking parameters and the matching
to the SM, and the file SusyTC.m, which includes the formulas for the sparticle spec-
trum and SUSY threshold correction calculations. Both files can be downloaded from
http://particlesandcosmology.unibas.ch/pages/SusyTC.htm and have to be copied
into the REAP directory.
To begin a calculation with SusyTC, one first needs to import RGEMSSMsoftbroken.m:
Needs["REAP‘RGEMSSMsoftbroken‘"];
The model MSSMsoftbroken is then defined by RGEAdd, including additional options such
as RGEtanβ:
RGEAdd["MSSMsoftbroken",RGEtanβ → 30];
– 16 –
JHEP07(2016)108
In MSSMsoftbroken all REAP options of the model MSSM are available. The options addition-
ally available in SusyTC are given in appendix C. The input is given by RGESetInitial.
Let us illustrate some features of SusyTC: to test for example the GUT scale prediction
for the Yukawa coupling ratioyµys
= 6, considering a given example parameter point in the
Constrained MSSM, one can type:
RGESetInitial[2·10∧16,RGEYd → DiagonalMatrix[{1.2·10∧-3, 2.2·10∧-3, 0.16}],RGEYe → DiagonalMatrix[{1.2·10∧-3, 6·2.2·10∧-3, 0.16}],RGEM12 → 2000, RGEA0 → 1000, RGEm0 → 3000];
Of course, any general matrices can be used as input for the Yukawa, trilinear, and soft-
breaking matrices, as given by the specific SUSY flavour GUT model under consideration.
Also, non-universal gaugino masses can be specified. As in REAP, dimensional quantities
are given in units of GeV. The RGEs are then solved from the GUT scale to the Z-boson
mass scale by
RGESsolve[91,2·10∧16];
The ratio of the µ and strange quark Yukawa couplings at the Z-boson mass scale can now
be obtained with RGEGetSolution, CKMParameters, and MNSParameters:
Yu = RGEGetSolution[91, RGEYu];
Yd = RGEGetSolution[91, RGEYd];
Ye = RGEGetSolution[91, RGEYe];
Mν = RGEGetSolution[91, RGEMν];
MNSParameters[Mν,Ye][[3, 2]]/CKMParameters[Yu, Yd][[3, 2]]
Repeating this calculation with all SU(5) CG factors listed in table 2 of [12], one obtains
the results shown in figure 8.
As described in appendix C, SusyTC can also read and write “Les Houches” files [55, 58]
as input and output.
5 The sparticle spectrum predicted from CG factors
In this section we apply SusyTC to investigate the constraints on the sparticle spectrum
which arise from a set of GUT scale predictions for the quark-lepton Yukawa coupling ratiosyeyd
,yµys
, and yτyb
. As GUT scale boundary conditions for the SUSY-breaking terms we take the
Constrained MSSM. The experimental constraints are given by the Higgs boson mass mh0 =
125.09± 0.21± 0.11 GeV [68] as well as the charged fermion masses (and the quark mixing
matrix). We use the experimental constraints for the running MS Yukawa couplings at the
Z-boson mass scale calculated in [36], where we set the uncertainty of the charged lepton
Yukawa couplings to one percent to account for the estimated theoretical uncertainty (which
here exceeds the experimental uncertainty). When applying the measured Higgs mass as
constraint, we use a 1σ interval of ±3 GeV, including the estimated theoretical uncertainty.
– 17 –
JHEP07(2016)108
+ ++ +
+
+
+
+
1-3/2-3 9/2 6 90
1
2
3
4
CG
yμys
Figure 8. Example results foryµys
at the electroweak scale, considering the SU(5) GUT-scale CG
factors from table 2 of [12], i.e. the GUT predictionsyµys
= CG, for a given example Constrained
MSSM parameter point with tan β = 30, m1/2 = 2000 GeV, A0 = 1000 GeV, and m0 = 3000 GeV.
The area between the dashed gray lines corresponds to the experimental 1σ range [36].
For our study, we consider GUT scale Yukawa coupling matrices which feature the
GUT-scale Yukawa relations yeyd
= −12 ,
yµys
= 6, and yτyb
= −32 (cf. [12]):
Yd =
yd 0 0
0 ys 0
0 0 yb
, Ye =
−1
2yd 0 0
0 6ys 0
0 0 −32yb
,
Yu =
yu 0 0
0 yc 0
0 0 yt
UCKM(θ12, θ13, θ23, δ) , (5.1)
These GUT relations can emerge as direct result of CG factors in SU(5) GUTs or as
approximate relation after diagonalization of the GUT-scale Yukawa matrices Yd and Ye(cf. [34, 35, 43, 44]). For the soft-breaking parameters we restrict our analysis to the
Constrained MSSM parameters m0, m1/2, A0 and tanβ, with µ determined from requiring
the breaking of electroweak symmetry as in (3.36) and set sgn(µ) = +1. We note that in
specific models for the GUT Higgs potential, for instance in [43], µ can be realized as an
effective parameter of the superpotential with a fixed phase, including the case that µ is real.
We note that we have also added a neutrino sector, i.e. a neutrino Yukawa matrix Yνand and a mass matrix Mn of the right-handed neutrinos, but we have set the entries of
Yν to very small values below O(10−3), such that their effects on the RG evolution can
be safely neglected, and the masses of the right-handed neutrinos to values many orders
of magnitude higher than the expected SUSY scale. With these parameters, the neutrino
– 18 –
JHEP07(2016)108
sector is decoupled from the main analysis. Such small values of the neutrino Yukawa
couplings are e.g. expected in the models [34, 35, 44], where they arise as effective operators.
Using one-loop RGEs, REAP 1.11.3 and SusyTC 1.1 we determine the soft-breaking
parameters and µ at the SUSY scale, as well as the pole mass mH+ . This output is then
passed to FeynHiggs 2.11.3 [60–67] in order to calculate the two-loop corrected pole masses
of the Higgs bosons in the complex MSSM. The MSSM is automatically matched to the
SM and we compare the results for the Yukawa couplings at the Z-boson mass scale with
the experimental values reported in [36].
When fitting the GUT-scale parameters to the experimental data, we found that our
results for the up-type quark Yukawa couplings and CKM angles and CP-phase could
be fitted to agree with observations to at least 10−3 relative precision, by adjusting the
parameters of Yu. The remaining six parameters are used to fit the Yukawa couplings of
down-type quarks and charged leptons, as well as the mass of the SM-like Higgs boson.
We find a benchmark point with a χ2 = 0.9:
input GUT scale parameters
yd ys yb
8.92 · 10−5 1.57 · 10−3 0.109
m0 A0 m1/2 tanβ
1629.48 GeV −3152.70 GeV 1840.48 GeV 21.27
low energy results
ye yµ yτ
2.79 · 10−6 5.90 · 10−4 1.00 · 10−2
yd ys yb mh0
1.75 · 10−5 3.07 · 10−4 1.64 · 10−2 123.6 GeV
Looking at our results for the low-energy Yukawa coupling ratios, yeyd
= 0.16,yµys
= 1.92,
and yτyb
= 0.61, the importance of SUSY threshold corrections in evaluating the GUT-scale
Yukawa ratios becomes evident. This can also be seen in figure 9. Additionally, as shown
in figure 10, SUSY threshold corrections also affect the CKM mixing angles.
The SUSY spectrum obtained by SusyTC is shown in figure 11. The lightest super-
symmetric particle (LSP) is a bino-like neutralino of about 827 GeV. The SUSY scale is
obtained as Q = 3014 GeV. The µ parameter obtained from requiring spontaneous elec-
troweak symmetry breaking is given by µ = 2634 GeV. Note that the only experimental
constraints we used were the results for quark and charged lepton masses as well as mh0 . In
particular, no bounds on the sparticle masses were applied as well as no restrictions from
the neutralino relic density (which would require further assumptions on the cosmological
evolution).6
6For example, the neutralino relic density may be diluted if additional entropy gets produced at late
times. Therefore we do not use the neutralino relic density as a constraint here.
– 19 –
JHEP07(2016)108
Due to the large (absolute) values of the trilinear couplings, we find using the con-
straints from [69], that the vacuum of our benchmark point is meta-stable. The scalar
potential possesses charge and colour breaking (CCB) vacua, as well as one “unbounded
from below” (UFB) field direction in parameter space. However, estimating the stability
of the vacuum via the Euclidean action of the “bounce” solution [70, 71] (following [72])
shows that the lifetime of the vacuum is many orders larger than the age of the universe.
Confidence intervals for the sparticle masses are obtained as Bayesian “highest pos-
terior density” (HPD) intervals7 from a Markov Chain Monte Carlo sample of 1.2 million
points, using a Metropolis algorithm. We note that we did not compute the lifetime of
the vacuum for each point in the MCMC analysis, which would take far too much com-
putation time. This means that the obtained confidence intervals should be regarded as
conservative, in the sense that including the lifetime constraints the upper bounds on the
masses could become smaller. For some example points within the 1σ HPD regions we have
checked that the lifetime constraints are satisfied. We applied the following priors to the
MCMC analysis: m0 ∈ [0, 4] TeV, A0 ∈ [−10, 0] TeV, m1/2 ∈ [0, 6] TeV and tan β ∈ [2, 40].
As shown in figure 12 our results for the 1σ HPD intervals for the Constrained MSSM soft-
breaking parameters are well within these intervals. The 1σ HPD results of the sparticle
masses are shown in figure 13. Furthermore we find that for about 70% of the data points
of the MCMC analysis, the lightest MSSM sparticle is a neutralino, while for the others
it is the lightest charged slepton.8 The HPD interval for the SUSY scale is obtained as
QHPD = [2048, 5108] GeV.
5.1 Comments and discussion
We would like to emphasize that the results described above have been obtained under
specific assumptions for the input parameters at the GUT scale. In the following, we
discuss these assumptions, how they may be obtained and/or generalized in fully worked
out models, and also some limitations and uncertainties of our analysis.
To start with, we have chosen the specific GUT scale predictions yτyb
= −32 ,
yµys
= 6 andyeyd
= −12 . This is indeed only one of the possible predictions that can arise from GUTs.
Other possibilities can be found, e.g., in [11–13]. We have chosen the above set of GUT
predictions since they are among the ones recently used successfully in GUT model building
(see e.g. [34, 35, 43, 44]). In the future, it will of course be interesting to also test other
combinations of promising Clebsch factors, and compare the predictions/constraints on the
SUSY spectra. Of course, one can also construct GUT models which do not predict the
quark-lepton Yukawa ratios. For such GUT models the constraints discussed here would
not apply.
Furthermore, for our study we have assumed CMSSM boundary conditions for the
soft breaking parameters, which is quite a strong assumption that will probably often
be relaxed in realistic models. On the other hand, universal boundary conditions may
also be a result of a specific SUSY breaking mechanism. Apart from the SUSY breaking
7An 1σ HPD interval is the interval [θL,θH ] such that∫ θHθL
p(θ)dθ = 0.6826 . . . and the posterior proba-
bility density p(θ) inside the interval is higher than for any θ outside of the interval [73].8Note that since in the latter case the LSP may be the gravitino, we do not exclude those points.
– 20 –
JHEP07(2016)108
mechanism, GUTs themselves “unify” the soft breaking parameters since they unify the
different types of SM fermions in GUT representations. In SU(5) GUTs, for example, one
is left with only two soft breaking mass matrices at the GUT scale per family, one for the
sfermions in the five-dimensional matter representation and one for the sfermions in the
ten-dimensional representation. In SO(10) GUTs, there is only one unified sfermion mass
matrix. In addition, the symmetries of GUT flavour models like [34, 35, 43, 44] include
various (non-Abelian) “family symmetries”, which lead to hierarchical Yukawa matrices
and impose (partially) universal soft breaking mass matrices among different generations.
The combination of these effects can indeed lead to GUT scale boundary conditions close to
the CMSSM. Finally, we like to note that the absence of deviations from the SM in flavour
physics processes leads to constraints on flavour non-universalities in the SUSY spectrum
(if the sparticles are not too heavy) and can be seen as an experimental hint that, if SUSY
exists at a comparably low scale, it should indeed be close to flavour-universal. In any case,
it will be interesting to see how the constraints on the SUSY spectrum change when the
assumption of an exact CMSSM at the GUT scale is relaxed.
On the other hand, although we have analyzed here a specific example only, some of
the key effects that lead to a predicted sparticle spectrum seem rather general, as long as
the quark-lepton Yukawa ratios are predicted at the GUT scale together with (close-to)
universal soft-breaking parameters (which we assume for the remainder of this discussion):
• The main reason for the predictions/constraints on the SUSY spectrum is the fact
that (to our knowledge) all the possible sets of GUT predictions for the quark-lepton
Yukawa ratios require a certain amount of SUSY threshold corrections for each gener-
ation.9 In general, to obtain the required size of the threshold corrections, one cannot
have a sparticle spectrum which is too “split” (as e.g. in [74, 75]), since otherwise
the loop functions (cf. section 3) get too suppressed. More specifically, the required
threshold corrections constrain the ratios of trilinear couplings, gaugino masses, µ and
sfermion masses. In a CMSSM-like scenario, this means the ratios between m0, m1/2
and A0 are constrained. Furthermore, since the most relevant threshold corrections
are the ones which are tan β-enhanced, tan β cannot bee too small.
• Finally, with the ratios between m0, m1/2 and A0 constrained and a moderate to large
value of tan β, the measured value of the mass mh of the SM-like Higgs boson allows
to constrain the SUSY scale. We note that this is an important ingredient, since
the threshold corrections themselves depend only on the ratios of trilinear couplings,
gaugino masses, µ and sfermion masses, and do not constrain the overall scale of the
soft breaking parameters. The combination of the two effects leads to the result of a
predicted sparticle spectrum from the assumed GUT boundary conditions.
Since mh plays an important role, we would like to comment that it would be highly
desirable to have a more precise computation of the Higgs mass available for the “large stop-
mixing” regime. As discussed above, we use a theoretical uncertainty of ±3 GeV, which
9One comment is in order here: in the CMSSM the SUSY threshold corrections are very similar for
the first two families, and therefore the argument remains valid even if the quark-lepton Yukawa ratios are
predicted for only two of the families, for the third family and either the second or the first family.
– 21 –
JHEP07(2016)108
is dominating the 1σ interval for mh entering our fit. This theoretical uncertainty should,
strictly speaking, not be treated on the same footing as a pure statistical uncertainty (but
the same of course also holds true for systematic experimental uncertainties). Furthermore,
there are indications that the theoretical uncertainty in the mh calculation in the most
relevant regions of parameter space of our analysis may be larger, as recently discussed e.g.
in [76], however there is no full agreement on this aspect. For our analysis we have used
the external software FeynHiggs 2.11.3, the current version when our numerical analysis
was performed, and the most commonly assumed estimate ±3 GeV for the theoretical
uncertainty.
One may also ask why we did not emphasize the aspect of gauge coupling unification.
From a bottom-up perspective, one could indeed conclude that in order to make the gauge
couplings meet at high energy, the SUSY scale cannot be too high. However, in realistic
GUTs, such statements are strongly affected by GUT threshold corrections. They can be
implemented easily with REAP once the specific GUT model is known, however they are
very model-dependent. In particular, for more general GUT-Higgs potentials it is known
that gauge coupling unification is not resulting in a relevant constraint on the SUSY scale.
For our analysis, we have therefore simply set the GUT scale to 2×1016 GeV. In an explicit
model, where the GUT threshold corrections can be computed and in particular if they
significantly shift the GUT scale, we expect that the predictions for the SUSY spectrum
will also be modified correspondingly, e.g. due to the increased amount of RG evolution.
Let us also comment on the fact that SusyTC is matching the MSSM to the SM at one
common “SUSY scale”. This is certainly a limitation of the current version of SusyTC. On
the other hand, as discussed above, in the scenarios where SUSY threshold corrections play
an important role, the sparticle spectrum cannot be too “split”. This means that for the
main applications of SusyTC, like the example presented in this section, one-step matching
is sufficiently accurate.
6 Summary and conclusion
In this work we discussed how predictions for the sparticle spectrum can arise from GUTs,
which feature predictions for the ratios of quark and lepton Yukawa couplings at high
energy. To test them by comparing with the experimental data, the RG running between
high and low energy has to be performed with sufficient accuracy, including threshold
corrections. In SUSY theories, the one-loop threshold corrections when matching the SUSY
model to the SM are of particular importance, since they can be enhanced by tan β or large
trilinear couplings, and thus have the potential to strongly affect the quark-lepton mass
relations. Since the SUSY threshold corrections depend on the SUSY parameters, they link
a given GUT flavour model to the SUSY model. In other words, via the SUSY threshold
corrections, GUT models can predict properties of the sparticle spectrum from the pattern
of quark-lepton mass ratios at the GUT scale.
To accurately study such predictions, we extend and generalize various formulas in
the literature which are needed for a precision analysis of SUSY flavour GUT models: for
example, we extend the RGEs for the MSSM soft breaking parameters at two-loop by the
– 22 –
JHEP07(2016)108
additional terms in the seesaw type-I extension (cf. appendix A). We generalize the one-loop
calculation of µ and pole mass calculation of mA and mH+ to include inter-generational
mixing in the self energies (cf. appendix B). Furthermore, we calculate the full one-loop
SUSY threshold corrections for the down-type quark, up-type quark and charged lepton
Yukawa coupling matrices in the electroweak unbroken phase (cf. section 3).
We introduce the new software tool SusyTC, a major extension to the Mathemat-
ica package REAP, where these formulas are implemented. In addition, SusyTC calculates
the DR sparticle spectrum and the SUSY scale Q, and can provide output in SLHA “Les
Houches” files which are the necessary input for external software, e.g. for performing a two-
loop Higgs mass calculation. REAP extended by SusyTC accepts general GUT scale Yukawa,
trilinear and soft breaking mass matrices as well as non-universal gaugino masses as input,
performs the RG evolution (integrating out the right-handed neutrinos at their mass thresh-
olds in the type I seesaw extension of the MSSM) and automatically matches the MSSM to
the SM, making it a convenient tool for top-down analyses of SUSY flavour GUT models.
We applied SusyTC to study the predictions for the parameters of the Constrained
MSSM SUSY scenario from the set of GUT-scale Yukawa relations yeyd
= −12 ,
yµys
= 6,
and yτyb
= −32 , which has been proposed recently in the context of GUT flavour models.
With a Markov Chain Monte Carlo analysis we find a “best-fit” benchmark point as well
as the 1σ Bayesian confidence intervals for the sparticle masses. Without applying any
constraints from LHC SUSY searches or dark matter, we find that the considered GUT
scenario predicts a sparticle spectrum above past LHC sensitivities, but partly within
reach of (a high-luminosity upgrade of) the LHC, and possibly fully testable at a future
O(100 TeV) pp collider like the FCC-hh [80] or the SPPC [81].
Acknowledgments
We would like to thank Vinzenz Maurer for help with code optimisation and Christian
Hohl for testing. We also thank Eros Cazzato, Thomas Hahn, Vinzenz Maurer, Stefano
Orani and Sebastian Paßehr for useful discussions. This work has been supported by the
Swiss National Science Foundation.
A The β-functions in the seesaw type-I extension of the MSSM
In this appendix we list the β-functions of the SUSY soft-breaking parameters in the MSSM
extended by the additional terms in the seesaw type-I extension (obtained using the general
formulas of [56]). Our conventions for W and Lsoft are given in (3.1) and (3.2).
A.1 One-loop β-functions
16π2βM1 =66
5g21M1 , (A.1)
16π2βM2 = 2g22M2 , (A.2)
16π2βM3 = −6g23M3 , (A.3)
– 23 –
JHEP07(2016)108
yeyd
yμys
yτyb
102 104 106 108 1010 1012 1014 1016
1
0.5
2
6
RG scale (GeV)
Figure 9. RG evolution of the Yukawa coupling ratios of the first, second and third family from
the GUT-scale to the mass scale of the Z-boson. The GUT scale parameters correspond to our
benchmark point from section 5. The effects of the threshold corrections are clearly visible at the
SUSY scale Q = 3015 GeV. The light gray areas indicate the experimental Yukawa coupling ratios
at MZ , taken from [36].
16π2βTu = Yu
(2Y †d Td + 4Y †uTu
)+ Tu
(Y †d Yd + 5Y †uYu
)+ Yu
(6 Tr(Y †uTu) + 2 Tr(Y †ν Tν) +
26
15g21M1 + 6g22M2 +
32
3g23M3
)+ Tu
(3 Tr(Y †uYu) + Tr(Y †ν Yν)− 13
15g21 − 3g22 −
16
3g23
), (A.4)
16π2βTd = Yd
(4Y †d Td + 2Y †uTu
)+ Td
(5Y †d Yd + Y †uYu
)+ Yd
(6 Tr(Y †d Td) + 2 Tr(Y †e Te) +
14
15g21M1 + 6g22M2 +
32
3g23M3
)+ Td
(3 Tr(Y †d Yd) + Tr(Y †e Ye)−
7
15g21 − 3g22 −
16
3g23
), (A.5)
16π2βTe = Ye
(4Y †e Te + 2Y †ν Tν
)+ Te
(5Y †e Ye + Y †ν Yν
)+ Ye
(6 Tr(Y †d Td) + 2 Tr(Y †e Te) +
18
5g21M1 + 6g22M2
)+ Te
(3 Tr(Y †d Yd) + Tr(Y †e Ye)−
9
5g21 − 3g22
), (A.6)
– 24 –
JHEP07(2016)108
θ13CKM
102 104 106 108 1010 1012 1014 10160.16o
0.17o
0.18o
0.19o
0.20o0.21o0.22o
θ23CKM
102 104 106 108 1010 1012 1014 10161.9o
2.0o2.1o2.2o2.3o2.4o2.5o
RG scale (GeV)
Figure 10. RG evolution of the CKM mixing angles θCKM13 and θCKM
23 from the GUT-scale to
the mass scale of the Z-boson. The GUT scale parameters correspond to our benchmark point
from section 5. The effects of the threshold corrections are clearly visible at the SUSY scale
Q = 3015 GeV. The light gray areas indicate the experimental values at MZ .
16π2βTν = Yν
(4Y †ν Tν + 2Y †e Te
)+ Tν
(5Y †ν Yν + Y †e Ye
)+ Yν
(6 Tr(Y †uTu) + 2 Tr(Y †ν Tν) +
6
5g21M1 + 6g22M2
)+ Tν
(3 Tr(Y †uYu) + Tr(Y †ν Yν)− 3
5g21 − 3g22
), (A.7)
16π2βm2L
= 2Y †em2eYe + 2Y †νm
2νYν
+m2L
(Y †e Ye + Y †ν Yν
)+(Y †e Ye + Y †ν Yν
)m2L
+ 2m2HuY
†ν Yν + 2m2
HdY †e Ye + 2T †eTe + 2T †νTν
− 6
5g21|M1|2 13 − 6g22|M2|2 13 −
3
5g21S 13 , (A.8)
16π2βm2Q
= 2Y †um2uYu + 2Y †dm
2dYd
+m2Q
(Y †uYu + Y †d Yd
)+(Y †uYu + Y †d Yd
)m2Q
+ 2m2HuY
†uYu + 2m2
HdY †d Yd + 2T †uTu + 2T †dTd
− 2
15g21|M1|2 13 − 6g22|M2|2 13 −
32
3g23|M3|2 13 +
1
5g21S 13 , (A.9)
– 25 –
JHEP07(2016)108
h10
h20 h3
0
H±
g
χ˜10
χ˜20
χ˜30
χ˜40
χ˜1±
χ˜2±
u˜i
d˜i
e˜i
ν˜i
100
200
500
1000
2000
5000Mas
s(GeV
)
Figure 11. SUSY spectrum with SU(5) GUT scale boundary conditions yeyd
= − 12 ,
yµys
= 6, andyτyb
= − 32 , corresponding to our benchmark point from section 5.
16π2βm2u
= 4Yum2QY †u + 2YuY
†um
2u + 2m2
uYuY†u
+ 4m2HuYuY
†u + 4TuT
†u
− 32
15g21|M1|2 13 −
32
3g23|M3|2 13 −
4
5g21S 13 , (A.10)
16π2βm2d
= 4Ydm2QY †d + 2YdY
†dm
2d
+ 2m2dYdY
†d
+ 4m2HdYdY
†d + 4TdT
†d
− 8
15g21|M1|2 13 −
32
3g23|M3|2 13 +
2
5g21S 13 , (A.11)
– 26 –
JHEP07(2016)108
tan β
0 10 20 30 40 50
m0
-A0
m1/2
2000 4000 6000 8000 10000
GeV
Figure 12. 1σ HPD intervals for the Constrained MSSM soft-breaking parameters.
16π2βm2e
= 4Yem2LY †e + 2YeY
†em
2e + 2m2
eYeY†e
+ 4m2HdYeY
†e + 4TeT
†e
− 24
5g21|M1|2 13 +
6
5g21S 13 , (A.12)
16π2βm2ν
= 4Yνm2LY †ν + 2YνY
†νm
2ν + 2m2
νYνY†ν
+ 4m2HuYνY
†ν + 4TνT
†ν , (A.13)
16π2βm2Hd
= 6 Tr(Ydm2QY †d + Y †dm
2dY d)
+ 2 Tr(Yem2LY †e + Y †em
2eYe)
+ 6m2Hd
Tr(Y †d Yd) + 2m2Hd
Tr(Y †e Ye)
+ 6 Tr(T †dTd) + 2 Tr(T †eTe)
− 6
5g21|M1|2 − 6g22|M2|2 −
3
5g21S , (A.14)
16π2βm2Hu
= 6 Tr(Yum2QY †u + Y †um
2uY u)
+ 2 Tr(Yνm2LY †ν + Y †νm
2νYν)
+ 6m2Hu Tr(Y †uYu) + 2m2
Hu Tr(Y †ν Yν)
+ 6 Tr(T †uTu) + 2 Tr(T †νTν)
− 6
5g21|M1|2 − 6g22|M2|2 +
3
5g21S , (A.15)
with
S = m2Hu −m2
Hd+ Tr
(m2Q−m2
L+m2
d+m2
e − 2m2u
). (A.16)
– 27 –
JHEP07(2016)108
h10
h20 h3
0
H±
χ 10
χ 20
χ 30 χ 4
0
χ 1±
χ 2±
g
u id i
ei
νi
100
500
1000
5000
104Mas
s(GeV
)
Figure 13. 1σ HPD intervals for the sparticle spectrum and Higgs boson masses with SU(5) GUT
scale boundary conditions yeyd
= − 12 ,
yµys
= 6, and yτyb
= − 32 . For about 70% of the data points, the
LSP is the lightest neutralino χ01.
A.2 Two-loop β-functions
(16π2)2β(2)M1
=12
5g2
1 Tr(TνY†ν ) +
28
5g2
1 Tr(TdY†d ) +
36
5g2
1 Tr(TeY†e ) +
52
5g2
1 Tr(TuY†u )
− 12
5g2
1M1 Tr(YνY†ν )− 28
5g2
1M1 Tr(YdY†d )
− 36
5g2
1M1 Tr(YeY†e )− 52
5g2
1M1 Tr(YuY†u )
+176
5g2
1g23M1 +
176
5g2
1g23M3 +
54
5g2
1g22M1 +
54
5g2
1g22M2 +
796
25g4
1M1 , (A.17)
(16π2)2β(2)M2
= 4g22 Tr(TνY
†ν ) + 4g2
2 Tr(TeY†e ) + 12g2
2 Tr(TdY†d ) + 12g2
2 Tr(TuY†u )
− 4g22M2 Tr(YνY
†ν )− 4g2
2M2 Tr(YeY†e )
− 12g22M2 Tr(YuY
†u )− 12g2
2M2 Tr(YdY†d )
– 28 –
JHEP07(2016)108
+18
5g2
1g22M1 +
18
5g2
1g23M2 + 48g2
2g23M2 + 48g2
2g23M3 + 100g4
2M2 , (A.18)
(16π2)2β(2)M3
= 8g23 Tr(TdY
†d ) + 8g2
3 Tr(TuY†u )− 8g2
3M3 Tr(YdY†d )− 8g2
3M3 Tr(YuY†u )
+22
5g2
1g23M1 +
22
5g2
1g23M3 + 18g2
2g23M2 + 18g2
2g23M3 + 56g4
3M3 , (A.19)
(16π2)2β(2)Tu
= −2Tu
(Y †d YdY
†d Yd + 2Y †d YdY
†uYu + 3Y †uYuY
†uYu
)− 2Yu
(2Y †d TdY
†d Yd + 2Y †d TdY
†uYu + 2Y †d YdY
†d Td
+ Y †d YdY†uTu + 4Y †uTuY
†uYu + 3Y †uYuY
†uTu
)− Tu
(Y †d Yd Tr(YeY
†e + 3YdY
†d ) + 5Y †uYu Tr(YνY
†ν + 3YuY
†u ))
− 2Yu
(Y †d Td Tr(YeY
†e + 3YdY
†d ) + Y †d Yd Tr(TeY
†e + 3TdY
†d )
+ 2Y †uTu Tr(YνY†ν + 3YuY
†u ) + 3Y †uYu Tr(TνY
†ν + 3TuY
†u ))
− Tu(
Tr(3YνY†ν YνY
†ν + YνY
†e YeY
†ν ) + 3 Tr(YuY
†d YdY
†u + 3YuY
†uYuY
†u ))
− 2Yu
(Tr(6TνY
†ν YνY
†ν + TνY
†e YeY
†ν + YνY
†e TeY
†ν )
+ 3 Tr(YuY†d TdY
†u + TuY
†d YdY
†u + 6TuY
†uYuY
†u ))
+2
5g2
1
(TuY
†d Yd + 2YuY
†d Td + 3YuY
†uTu − 2M1(YuY
†d Yd + YuY
†uYu)
)+ 6g2
2
(YuY
†uTu + 2TuY
†uYu − 2M2YuY
†uYu
)+
(16g2
3 +4
5g2
1
)(2Yu Tr(Y †uTu) + Tu Tr(Y †uYu)
)+
136
45g2
1g23Tu +
15
2g4
2Tu −16
9g4
3Tu +2743
450g4
1Tu + g21g
22Tu + 8g2
2g23Tu
− Yu Tr(Y †uYu)
(32g2
3M3 +8
5g2
1M1
)− 272
45g2
1g23Yu(M1 +M3)
− 2g21g
22Yu(M1 +M2)− 16g2
2g23Yu(M2 +M3)
− 30g42M2Yu −
5486
225g4
1M1Yu +64
9g4
3M3Yu , (A.20)
(16π2)2β(2)Td
= −2Td
(3Y †d YdY
†d Yd + 2Y †uYuY
†d Yd + Y †uYuY
†uYu
)− 2Yd
(4Y †d TdY
†d Yd + 3Y †d YdY
†d Td + 2Y †uTuY
†d Yd
+ 2Y †uTuY†uYu + Y †uYuY
†d Td + 2Y †uYuY
†uTu
)− Td
(5Y †d Yd Tr(YeY
†e + 3YdY
†d ) + Y †uYu Tr(YνY
†ν + 3YuY
†u ))
− 2Yd
(2Y †d Td Tr(YeY
†e + 3YdY
†d ) + 3Y †d Yd Tr(TeY
†e + 3TdY
†d )
+ Y †uTu Tr(YνY†ν + 3YuY
†u ) + Y †uYu Tr(TνY
†ν + 3TuY
†u ))
− Td(
Tr(YeY†ν YνY
†e + 3YeY
†e YeY
†e ) + 3 Tr(YuY
†d YdY
†u + 3YdY
†d YdY
†d ))
− 2Yd
(Tr(YeY
†ν TνY
†e + TeY
†ν YνY
†e + 6TeY
†e YeY
†e )
+ 3 Tr(TdY†uYuY
†d + TuY
†d YdY
†u + 6TdY
†d YdY
†d ))
– 29 –
JHEP07(2016)108
+2
5g2
1
(2TdY
†uYu + 3TdY
†d Yd + 3YdY
†d Td + 4YdY
†uTu − 4M1(YdY
†d Yd + YdY
†uYu)
)+ 6g2
2
(YdY
†d Td + 2TdY
†d Yd − 2M2YdY
†d Yd
)+
(16g2
3 −2
5g2
1
)(2Yd Tr(Y †d Td) + Td Tr(Y †d Yd)
)+
6
5g2
1
(2Yd Tr(Y †e Te) + Td Tr(Y †e Ye)
)+
8
9g2
1g23Td +
15
2g4
2Td −16
9g4
3Td +287
90g4
1Td + g21g
22Td + 8g2
2g23Td
− Yd Tr(Y †d Yd)
(32g2
3M3 −4
5g2
1M1
)− 12
5g2
1M1Yd Tr(Y †e Ye)
− 16
9g2
1g23Yd(M1 +M3)− 2g2
1g22Yd(M1 +M2)− 16g2
2g23Yd(M2 +M3)
− 30g42M2Yd −
574
45g4
1M1Yd +64
9g4
3M3Yd , (A.21)
(16π2)2β(2)Te
= −2Te
(3Y †e YeY
†e Ye + 2Y †ν YνY
†e Ye + Y †ν YνY
†ν Yν
)− 2Ye
(4Y †e TeY
†e Ye + 3Y †e YeY
†e Te + 2Y †ν TνY
†e Ye
+ 2Y †ν TνY†ν Yν + Y †ν YνY
†e Te + 2Y †ν YνY
†ν Tν
)− Te
(5Y †e Ye Tr(YeY
†e + 3YdY
†d ) + Y †ν Yν Tr(YνY
†ν + 3YuY
†u ))
− 2Ye
(2Y †e Te Tr(YeY
†e + 3YdY
†d ) + 3Y †e Ye Tr(TeY
†e + 3TdY
†d )
+ Y †ν Tν Tr(YνY†ν + 3YuY
†u ) + Y †ν Yν Tr(TνY
†ν + 3TuY
†u ))
− Te(
Tr(YeY†ν YνY
†e + 3YeY
†e YeY
†e ) + 3 Tr(YdY
†uYuY
†d + 3YdY
†d YdY
†d ))
− 2Ye
(Tr(YeY
†ν TνY
†e + TeY
†ν YνY
†e + 6TeY
†e YeY
†e )
+ 3 Tr(TdY†uYuY
†d + TuY
†d YdY
†u + 6TdY
†d YdY
†d ))
+6
5g2
1
(YeY
†e Te − TeY †e Ye
)+ 6g2
2
(YeY
†e Te + 2TeY
†e Ye − 2M2YeY
†e Ye
)+
(16g2
3 −2
5g2
1
)(2Ye Tr(Y †d Td) + Te Tr(Y †d Yd)
)+
6
5g2
1
(2Ye Tr(Y †e Te) + Te Tr(Y †e Ye)
)+
15
2g4
2Te +27
2g4
1Te +9
5g2
1g22Te
− Ye Tr(Y †d Yd)
(32g2
3M3 −4
5g2
1M1
)− 12
5g2
1M1Ye Tr(Y †e Ye)
− 18
5g2
1g22Yd(M1 +M2)− 30g4
2M2Ye − 54g41M1Ye , (A.22)
(16π2)2β(2)Tν
= −2Tν
(Y †e YeY
†e Ye + 2Y †e YeY
†ν Yν + 3Y †ν YνY
†ν Yν
)− 2Yν
(2Y †e TeY
†e Ye + 2Y †e TeY
†ν Yν + 2Y †e YeY
†e Te
+ Y †e YeY†ν Tν + 4Y †ν TνY
†ν Yν + 3Y †ν YνY
†ν Tν
)
– 30 –
JHEP07(2016)108
− Tν(Y †e Ye Tr(YeY
†e + 3YdY
†d ) + 5Y †ν Yν Tr(YνY
†ν + 3YuY
†u ))
− 2Yν
(Y †e Te Tr(YeY
†e + 3YdY
†d ) + Y †e Ye Tr(TeY
†e + 3TdY
†d )
+ 2Y †ν Tν Tr(YνY†ν + 3YuY
†u ) + 3Y †ν Yν Tr(TνY
†ν + 3TuY
†u ))
− Tν(
Tr(3YνY†ν YνY
†ν + YνY
†e YeY
†ν ) + 3 Tr(YuY
†d YdY
†u + 3YuY
†uYuY
†u ))
− 2Yν
(Tr(TνY
†e YeY
†ν + YνY
†e TeY
†ν + 6TνY
†ν YνY
†ν )
+ 3 Tr(TdY†uYuY
†d + TuY
†d YdY
†u + 6TuY
†uYuY
†u ))
+6
5g2
1
(2TνY
†ν Yν + 2YνY
†e Te + YνY
†ν Tν + TνY
†e Ye − 2M1(YνY
†ν Yν + YνY
†e Ye)
)+ 6g2
2
(YνY
†ν Tν + 2TνY
†ν Yν − 2M2YνY
†ν Yν
)+
(16g2
3 +4
5g2
1
)(2Yν Tr(Y †uTu) + Tν Tr(Y †uYu)
)+
15
2g4
2Tν +207
50g4
1Tν +9
5g2
1g22Tν
− Yν Tr(Y †uYu)
(32g2
3M3 +8
5g2
1M1
)− 18
5g2
1g22Yν(M1 +M2)− 30g4
2M2Yν −414
25g4
1M1Yν , (A.23)
(16π2)2β(2)
m2L
= −4T †e
(TeY
†e Ye + YeY
†e Te
)− 4T †ν
(TνY
†ν Yν + YνY
†ν Tν
)− 2Y †e
(2m2
eYeY†e Ye + 2TeT
†e Ye + 2YeT
†e Te
+2YeY†em
2eYe + YeY
†e Yem
2L
+ 2Yem2LY †e Ye
)− 2Y †ν
(2m2
νYνY†ν Yν + 2TνT
†νYν + 2YνT
†νTν
+2YνY†νm
2νYν + YνY
†ν Yνm
2L
+ 2Yνm2LY †ν Yν
)− 2
(4m2
Hd+m2
L
)Y †e YeY
†e Ye − 2
(4m2
Hu +m2L
)Y †ν YνY
†ν Yν
− 2T †e
(Te Tr(YeY
†e + 3YdY
†d ) + Ye Tr(TeY
†e + 3TdY
†d ))
− 2T †ν
(Tν Tr(YνY
†ν + 3YuY
†u ) + Yν Tr(TνY
†ν + 3TuY
†u ))
− Y †e(
2m2eYe Tr(YeY
†e + 3YdY
†d ) + 2Te Tr(YeT
†e + 3YdT
†d )
+ 2Ye Tr(TeT†e + 3TdT
†d ) + Yem
2L
Tr(YeY†e + 3YdY
†d ))
− Y †ν(
2m2νYν Tr(YνY
†ν + 3YuY
†u ) + 2Tν Tr(YνT
†ν + 3YuT
†u)
+ 2Yν Tr(TνT†ν + 3TuT
†u) + Yνm
2L
Tr(YνY†ν + 3YuY
†u ))
−(
4m2Hd
+m2L
)Y †e Ye Tr(YeY
†e + 3YdY
†d )
−(
4m2Hu +m2
L
)Y †ν Yν Tr(YνY
†ν + 3YuY
†u )
− 2Y †e Ye Tr(Yem
2LY †e + Y †em
2eYe + 3Ydm
2QY †d + 3Y †dm
2dYd
)− 2Y †ν Yν Tr
(Yνm
2LY †ν + Y †νm
2νYν + 3Yum
2QY †u + 3Y †um
2uYu
)+
6
5g2
1
(2m2
HdY †e Ye +m2
LY †e Ye + Y †e Yem
2L
+ 2Y †em2eYe + 2T †e Te
)
– 31 –
JHEP07(2016)108
− 12
5g2
1
(M∗1Y
†e Te − 2|M1|2Y †e Ye +M1T
†e Ye)
+621
25g4
1 |M1|2 13 +18
5g2
1g22(|M1|2 + |M2|2) 13
+18
5g2
1g22Re(M1M
∗2 ) 13 + 33g4
2 |M2|2 13
+3
5g2
1σ1 13 + 3g22σ2 13 −
6
5g2
1S′ 13 , (A.24)
(16π2)2β(2)
m2Q
= −4T †d
(TdY
†d Yd + YdY
†d Td
)− 4T †u
(TuY
†uYu + YuY
†uTu
)− 2Y †d
(2m2
dYdY
†d Yd + 2TdT
†dYd + 2YdT
†dTd
+2YdY†dm
2dYd + YdY
†d Ydm
2Q
+ 2Ydm2QY †d Yd
)− 2Y †u
(2m2
uYuY†uYu + 2TuT
†uYu + 2YuT
†uTu
+2YuY†um
2uYu + YuY
†uYum
2Q
+ 2Yum2QY †uYu
)− 2
(4m2
Hd+m2
Q
)Y †d YdY
†d Yd − 2
(4m2
Hu +m2Q
)Y †uYuY
†uYu
− 2T †d
(Td Tr(YeY
†e + 3YdY
†d ) + Yd Tr(TeY
†e + 3TdY
†d ))
− 2T †u
(Tu Tr(YνY
†ν + 3YuY
†u ) + Yu Tr(TνY
†ν + 3TuY
†u ))
− Y †d(
2m2dYd Tr(YeY
†e + 3YdY
†d ) + 2Td Tr(YeT
†e + 3YdT
†d )
+ 2Yd Tr(TeT†e + 3TdT
†d ) + Ydm
2Q
Tr(YeY†e + 3YdY
†d ))
− Y †u(
2m2uYu Tr(YνY
†ν + 3YuY
†u ) + 2Tu Tr(YνT
†ν + 3YuT
†u)
+ 2Yu Tr(TνT†ν + 3TuT
†u) + Yum
2Q
Tr(YνY†ν + 3YuY
†u ))
−(
4m2Hd
+m2Q
)Y †d Yd Tr(YeY
†e + 3YdY
†d )
−(
4m2Hu +m2
Q
)Y †uYu Tr(YνY
†ν + 3YuY
†u )
− 2Y †d Yd Tr(Yem
2LY †e + Y †em
2eYe + 3Ydm
2QY †d + 3Y †dm
2dYd
)− 2Y †uYu Tr
(Yνm
2LY †ν + Y †νm
2νYν + 3Yum
2QY †u + 3Y †um
2uYu
)+
2
5g2
1
(2m2
HdY †d Yd + 4m2
HuY†uYu +m2
QY †d Yd + Y †d Ydm
2Q
+ 2Y †dm2dYd
+ 2m2QY †uYu + 2Y †uYum
2Q
+ 4Y †um2uYu + 2T †dTd + 4T †uTu
)− 4
5g2
1
(M∗1Y
†d Td + 2M∗1Y
†uTu − 4|M1|2Y †uYu
+ M1T†dYd + 2M1T
†uYu − 2|M1|2Y †d Yd
)− 128
3g4
3 |M3|2 13 +2
5g2
1g22Re (M1M
∗2 ) 13 +
32
45g2
1g23Re (M1M
∗3 ) 13
+199
75g4
1 |M1|2 13 +2
5g2
1g22(|M1|2 + |M2|2) 13
+ 32g22g
23(|M2|2 +Re(M2M
∗3 ) + |M3|2) 13
+32
45g2
1g23(|M1|2 + |M3|2) 13 + 33g4
2 |M2|2 13
– 32 –
JHEP07(2016)108
+1
15g2
1σ1 13 + 3g22σ2 13 +
16
3g2
3σ3 13 +2
5g2
1S′ 13 , (A.25)
(16π2)2β(2)
m2u
= −2(
2m2Hd
+ 2m2Hu +m2
u
)YuY
†d YdY
†u − 2
(4m2
Hu +m2u
)YuY
†uYuY
†u
− 4Tu
(T †dYdY
†u + T †uYuY
†u + Y †d YdT
†u + Y †uYuT
†u
)− 4Yu
(T †dTdY
†u + T †uTuY
†u + Y †d TdT
†u + Y †uTuT
†u
)− 2Yu
(2Y †dm
2dYdY
†u + Y †d YdY
†um
2u + 2Y †d Ydm
2QY †u + 2Y †um
2uYuY
†u
+ Y †uYuY†um
2u + 2Y †uYum
2QY †u + 2m2
QY †d YdY
†u + 2m2
QY †uYuY
†u
)− 2
(4m2
Hu +m2u
)YuY
†u Tr(YνY
†ν + 3YuY
†u )
− 4Tu
(T †u Tr(YνY
†ν + 3YuY
†u ) + Y †u Tr(YνT
†ν + 3YuT
†u))
− 4Yu
(T †u Tr(TνY
†ν + 3TuY
†u ) + Y †u Tr(TνT
†ν + 3TuT
†u))
− 2Y †u
(Y †um
2u Tr(YνY
†ν + 3YuY
†u ) + 2m2
QY †u Tr(YνY
†ν + 3YuY
†u )
+ 2Y †u Tr(Yνm2LY †ν + Y †νm
2νYν + 3Yum
2QY †u + 3Y †um
2uYu)
)+
(6g2
2 −2
5g2
1
)(m2uYuY
†u + YuY
†um
2u + 2m2
HuYuY†u + 2Yum
2QY †u + 2TuT
†u
)− 12g2
2
(M∗2TuY
†u − 2|M2|2YuY †u +M2YuT
†u
)+
4
5g2
1
(M∗1TuY
†u − 2|M1|2YuY †u +M1YuT
†u
)− 128
3g4
3 |M3|2 13 +512
45g2
1g23
(|M1|2 +Re(M1M
∗3 ) + |M3|2
)13
+3424
75g4
1 |M1|2 13 +16
15g2
1σ1 13 +16
3g2
3σ3 13 −8
5g2
1S′ 13 , (A.26)
(16π2)2β(2)
m2d
= −2(
2m2Hd
+ 2m2Hu +m2
d
)YdY
†uYuY
†d − 2
(4m2
Hd+m2
d
)YdY
†d YdY
†d
− 4Td
(T †dYdY
†d + T †uYuY
†d + Y †d YdT
†d + Y †uYuT
†d
)− 4Yd
(T †dTdY
†d + T †uTuY
†d + Y †d TdT
†d + Y †uTuT
†d
)− 2Yd
(2Y †dm
2dYdY
†d + Y †d YdY
†dm
2d
+ 2Y †d Ydm2QY †d + 2Y †um
2uYuY
†d
+ Y †uYuY†dm
2d
+ 2Y †uYum2QY †d + 2m2
QY †d YdY
†d + 2m2
QY †uYuY
†d
)− 2
(4m2
Hd+m2
d
)YdY
†d Tr(YeY
†e + 3YdY
†d )
− 4Td
(T †d Tr(YeY
†e + 3YdY
†d ) + Y †d Tr(YeT
†e + 3YdT
†d ))
− 4Yd
(T †d Tr(TeY
†e + 3TdY
†d ) + Y †d Tr(TeT
†e + 3TdT
†d ))
− 2Y †d
(Y †dm
2d
Tr(YeY†e + 3YdY
†d ) + 2m2
QY †d Tr(YeY
†e + 3YdY
†d )
+ 2Y †d Tr(Yem2LY †e + Y †em
2eYe + 3Ydm
2QY †d + 3Y †dm
2dYd))
+
(6g2
2 +2
5g2
1
)(m2dYdY
†d + YdY
†dm
2d
+ 2m2HdYdY
†d + 2Ydm
2QY †d + 2TdT
†d
)− 12g2
2
(M∗2TdY
†d − 2|M2|2YdY †d +M2YdT
†d
)
– 33 –
JHEP07(2016)108
− 4
5g2
1
(M∗1TdY
†d − 2|M1|2YdY †d +M1YdT
†d
)− 128
3g4
3 |M3|2 13 +128
45g2
1g23
(|M1|2 +Re(M1M
∗3 ) + |M3|2
)13
+808
75g4
1 |M1|2 13 +4
15g2
1σ1 13 +16
3g2
3σ3 13 +4
5g2
1S′ 13 , (A.27)
(16π2)2β(2)
m2e
= −2(
2m2Hd
+ 2m2Hu +m2
e
)YeY
†ν YνY
†e − 2
(4m2
Hd+m2
e
)YeY
†e YeY
†e
− 4Te
(T †e YeY
†e + T †νYνY
†e + Y †e YeT
†e + Y †ν YνT
†e
)− 4Ye
(T †e TeY
†e + T †νTνY
†e + Y †e TeT
†e + Y †ν TνT
†e
)− 2Ye
(2Y †em
2eYeY
†e + Y †e YeY
†em
2e + 2Y †e Yem
2LY †e + 2Y †νm
2νYνY
†e
+ Y †ν YνY†em
2e + 2Y †ν Yνm
2LY †e + 2m2
LY †e YeY
†e + 2m2
LY †ν YνY
†e
)− 2
(4m2
Hd+m2
e
)YeY
†e Tr(YeY
†e + 3YdY
†d )
− 4Te
(T †e Tr(YeY
†e + 3YdY
†d ) + Y †e Tr(YeT
†e + 3YdT
†d ))
− 4Ye
(T †e Tr(TeY
†e + 3TdY
†d ) + Y †e Tr(TeT
†e + 3TdT
†d ))
− 2Y †e
(Y †em
2e Tr(YeY
†e + 3YdY
†d ) + 2m2
LY †e Tr(YeY
†e + 3YdY
†d )
+ 2Y †e Tr(Yem2LY †e + Y †em
2eYe + 3Ydm
2QY †d + 3Y †dm
2dYd))
+
(6g2
2 −6
5g2
1
)(m2eYeY
†e + YeY
†em
2e + 2m2
HdYeY
†e + 2Yem
2LY †e + 2TeT
†e
)− 12g2
2
(M∗2TeY
†e − 2|M2|2YeY †e +M2YeT
†e
)+
12
5g2
1
(M∗1TeY
†e − 2|M1|2YeY †e +M1YeT
†e
)+
2808
25g4
1 |M1|2 13 +12
5g2
1σ1 13 +12
5g2
1S′ 13 , (A.28)
(16π2)2β(2)
m2ν
= −2(
2m2Hd
+ 2m2Hu +m2
ν
)YνY
†e YeY
†ν − 2
(4m2
Hu +m2ν
)YνY
†ν YνY
†ν
− 4Tν
(T †e YeY
†ν + T †νYνY
†ν + Y †e YeT
†ν + Y †ν YνT
†ν
)− 4Yν
(T †e TeY
†ν + T †νTνY
†ν + Y †e TeT
†ν + Y †ν TνT
†ν
)− 2Yν
(2Y †em
2eYeY
†ν + Y †e YeY
†νm
2ν + 2Y †e Yem
2LY †ν + 2Y †νm
2νYνY
†ν
+ Y †ν YνY†νm
2ν + 2Y †ν Yνm
2LY †ν + 2m2
LY †e YeY
†ν + 2m2
LY †ν YνY
†ν
)− 2
(4m2
Hu +m2ν
)YνY
†ν Tr(YνY
†ν + 3YuY
†u )
− 4Tν
(T †ν Tr(YνY
†ν + 3YuY
†u ) + Y †ν Tr(YνT
†ν + 3YuT
†u))
− 4Yν
(T †ν Tr(TνY
†ν + 3TuY
†u ) + Y †ν Tr(TνT
†ν + 3TuT
†u))
− 2Y †ν
(Y †νm
2ν Tr(YνY
†ν + 3YuY
†u ) + 2m2
LY †ν Tr(YνY
†ν + 3YuY
†u )
+ 2Y †ν Tr(Yνm2LY †ν + Y †νm
2νYν + 3Yum
2QY †u + 3Y †um
2uYu)
)+
(6g2
2 +6
5g2
1
)(m2νYνY
†ν + YνY
†νm
2ν + 2m2
HuYνY†ν + 2Yνm
2LY †ν + 2TνT
†ν
)
– 34 –
JHEP07(2016)108
− 12g22
(M∗2TνY
†ν − 2|M2|2YνY †ν +M2YνT
†ν
)− 12
5g2
1
(M∗1TνY
†ν − 2|M1|2YνY †ν +M1YνT
†ν
), (A.29)
(16π2)2β(2)
m2Hd
= −2(m2Hd
+m2Hu
)Tr(YeY
†ν YνY
†e + 3YdY
†uYuY
†d )
− 12m2Hd
Tr(YeY†e YeY
†e + 3YdY
†d YdY
†d )
− 12 Tr(T †e TeY†e Ye + 3T †dTdY
†d Yd + T †e YeY
†e Te + 3T †dYdY
†d Td)
− 2 Tr(TeT†νYνY
†e + 3TdT
†uYuY
†d + TeY
†ν YνT
†e + 3TdY
†uYuT
†d )
− 2 Tr(YeT†νTνY
†e + 3YdT
†uTuY
†d + YeY
†ν TνT
†e + 3YdY
†uTuT
†d )
− 36 Tr(YdY†dm
2dYdY
†d + Y †d Ydm
2QY †d Yd)
− 12 Tr(YeY†em
2eYeY
†e + Y †e Yem
2LY †e Ye)
− 6 Tr(YuY†dm
2dYdY
†u + YdY
†um
2uYuY
†d + Y †uYum
2QY †d Yd + Y †d Ydm
2QY †uYu)
− 2 Tr(YνY†em
2eYeY
†ν + YeY
†νm
2νYνY
†e + Y †ν Yνm
2LY †e Ye + Y †e Yem
2LY †ν Yν)
+
(32g2
3 −4
5g2
1
)Tr(T †dTd +m2
HdY †d Yd + Ydm
2QY †d + Y †dm
2dYd)
+12
5g2
1 Tr(T †e Te +m2HdY †e Ye + Yem
2LY †e + Y †em
2eYe)
− 12
5g2
1 Tr(M∗1Y†e Te +M1T
†e Ye − 2|M1|2Y †e Ye)
+4
5g2
1 Tr(M∗1Y†d Td +M1T
†dYd − 2|M1|2Y †d Yd)
− 32g23 Tr(M∗3Y
†d Td +M3T
†dYd − 2|M3|2Y †d Yd)
+18
5g2
1g22
(|M1|2 +Re(M1M
∗2 ) + |M2|2
)+
621
25g4
1 |M1|2 + 33g42 |M2|2 +
3
5g2
1σ1 + 3g22σ2 −
6
5g2
1S′ , (A.30)
(16π2)2β(2)
m2Hu
= −2(m2Hd
+m2Hu
)Tr(YeY
†ν YνY
†e + 3YdY
†uYuY
†d )
− 12m2Hu Tr(YνY
†ν YνY
†ν + 3YuY
†uYuY
†u )
− 12 Tr(T †νTνY†ν Yν + 3T †uTuY
†uYu + T †νYνY
†ν Tν + 3T †uYuY
†uTu)
− 2 Tr(TeT†νYνY
†e + 3TdT
†uYuY
†d + TeY
†ν YνT
†e + 3TdY
†uYuT
†d )
− 2 Tr(YeT†νTνY
†e + 3YdT
†uTuY
†d + YeY
†ν TνT
†e + 3YdY
†uTuT
†d )
− 36 Tr(YuY†um
2uYuY
†u + Y †uYum
2QY †uYu)
− 12 Tr(YνY†νm
2νYνY
†ν + Y †ν Yνm
2LY †ν Yν)
− 6 Tr(YuY†dm
2dYdY
†u + YdY
†um
2uYuY
†d + Y †uYum
2QY †d Yd + Y †d Ydm
2QY †uYu)
− 2 Tr(YνY†em
2eYeY
†ν + YeY
†νm
2νYνY
†e + Y †ν Yνm
2LY †e Ye + Y †e Yem
2LY †ν Yν)
+
(32g2
3 +8
5g2
1
)Tr(T †uTu +m2
HuY†uYu + Yum
2QY †u + Y †um
2uYu)
− 8
5g2
1 Tr(M∗1Y†uTu +M1T
†uYu − 2|M1|2Y †uYu)
− 32g23 Tr(M∗3Y
†uTu +M3T
†uYu − 2|M3|2Y †uYu)
– 35 –
JHEP07(2016)108
+18
5g2
1g22
(|M1|2 +Re(M1M
∗2 ) + |M2|2
)+
621
25g4
1 |M1|2 + 33g42 |M2|2 +
3
5g2
1σ1 + 3g22σ2 +
6
5g2
1S′ , (A.31)
with
σ1 =1
5g21
(3m2
Hu + 3m2Hd
+ Tr(m2Q
+ 3m2L
+ 2m2d
+ 6m2e + 8m2
u
)), (A.32)
σ22 = g22
(m2Hu +m2
Hd+ Tr
(3m2
Q+m2
L
)), (A.33)
σ3 = g23 Tr(
2m2Q
+m2d
+m2u
), (A.34)
and
S′ = m2Hd
Tr(YeY
†e + 3YdY
†d
)−m2
Hu Tr(YνY
†ν + 3YuY
†u
)+ Tr
(m2LY †e Ye +m2
LY †ν Yν
)− Tr
(m2QY †d Yd +m2
QY †uYu
)− 2 Tr
(YdY
†dm
2d
+ YeY†em
2e − 2YuY
†um
2u
)+
1
30g21
(9m2
Hu − 9m2Hd
+ Tr(m2Q− 9m2
L+ 4m2
d+ 36m2
e − 32m2u
))+
3
2g22
(m2Hu −m2
Hd+ Tr
(m2Q−m2
L
))+
8
3g23 Tr
(m2Q
+m2d− 2m2
u
). (A.35)
B Self-energies and one-loop tadpoles including inter-generational mix-
ing
Here we present the used formulas for the self-energies ΠTZZ , ΠH+H− , ΠAA, and the one-loop
tadpoles tu, td, which are based on [59] but generalized to include inter-generational mixing.
In this appendix we employ SLHA 2 conventions [55] in the Super-CKM and Super-PMNS
basis, to agree with the convention of [59]. The soft-breaking mass matrices in the Super-
CKM/Super-PMNS basis are obtained from our flavour basis conventions (3.1) and (3.2) by
yf ≡ Y diagf = U †fYfVf ,
Tf ≡ U †fTfVf ,m2Q≡ V †dm2
QVd ,
m2L≡ V †em2
LVe ,
m2u ≡ U †um2
uUu ,
m2d≡ U †dm2
dUd ,
m2e ≡ U †em2
eUe . (B.1)
Let us briefly review our generalization to the sfermion mass matrices of [59]: we define
the sfermion mixing matrices by10
M2f
= WfM2 diag
fW †f, (B.2)
10The SLHA 2 convention sfermion mixing matrices Rf can be obtained via Rf = W †f
.
– 36 –
JHEP07(2016)108
with the sfermion mass matrices in the Super-CKM/Super-PMNS basis
M2u =
VCKMm2QV †CKM + v2
2 y2u sin2 β +Du,L
v√2T †u sinβ − µ v√
2yu cosβ
v√2Tu sinβ − µ∗ v√
2yu cosβ m2
u + v2
2 y2u sin2 β +Du,R
,
M2d
=
m2Q
+ v2
2 y2d cos2 β +Dd,L
v√2T †d cosβ − µ v√
2yd sinβ
v√2Td cosβ − µ∗ v√
2yd sinβ m2
d+ v2
2 y2d cos2 β +Dd,R
,
M2e =
m2L
+ v2
2 y2e cos2 β +De,L
v√2T †e cosβ − µ v√
2ye sinβ
v√2Te cosβ − µ∗ v√
2ye sinβ m2
e + v2
2 y2e cos2 β +De,R
,
M2ν = V †PMNSm
2LVPMNS +Dν,L . (B.3)
The D-terms are given by
Df,L = M2Z(I3 −Qe sin2 θW ) cos(2β) 13 ,
Df,R = M2ZQe cos(2β) sin2 θW 13 , (B.4)
where I3 denotes the SU(2)L isospin and Qe the electric charge of the flavour f , and θWdenotes the weak mixing angle. Note that our convention for µ differs by a sign from the
convention in [59].
For the sake of completeness we also list the conventions for neutralino and chargino
mass matrices and mixing matrices: the neutralino mixing matrix is defined by
Mψ0 = NTMdiagψ0 N , (B.5)
with
Mψ0 =
M1 0 −MZ cosβ sin θW MZ sinβ sin θW
0 M2 MZ cosβ cos θW −MZ sinβ cos θW
−MZ cosβ sin θW MZ cosβ cos θW 0 −µMZ sinβ sin θW −MZ sinβ cos θW −µ 0
.
(B.6)
The chargino mixing matrix is defined by
Mψ+ = UTMdiagψ+ V , (B.7)
with
Mψ+ =
(M2
√2MW sinβ
√2MW cosβ µ
). (B.8)
We now present the generalization of ΠTZZ , ΠH+H− , ΠAA, tu, and td of [59] to in-
clude inter-generational mixing. For all we have checked that our equations reduce to the
corresponding equations in [59] when
Wfi i= Wfi+3 i+3
= cos θfi
– 37 –
JHEP07(2016)108
Wfi i+3= −Wfi+3 i
= − sin θfi , (B.9)
where i = 1 . . . 3.
We keep the abbreviations of [59]:
sαβ ≡ sin(α− β) , (B.10)
cαβ ≡ cos(α− β) , (B.11)
gfL ≡ I3 −Qe sin2 θW , (B.12)
gfR ≡ Qe sin2 θW , (B.13)
e ≡ g2 sin θW , (B.14)
NC ≡{
3 for (s)quarks
1 for (s)fermions. (B.15)
The conventions for the one-loop scalar functions A0, B22, B22, H, G, and F [77, 78]
are adopted from appendix B of [59]. Summations∑
f are over all fermions, whereas
summations∑
fu,∑
fdare restricted to up-type and down-type fermions, respectively.
Summations∑
Q,∑
Q are over SU(2) (s)quark doublets, and analogously for (s)leptons.
In summations over sfermions the indices i, j, s, and t run from 1 to 6 for u, d, and e
and from 1 to 3 for ν. In summations of neutralinos (charginos) the indices i, j run from
1 to 4 (2). The summations∑
h0 runs over all neutral Higgs- and Goldstone bosons, the
summation∑
h+ over the charged ones.
16π2cos2 θWg22
ΠTZZ(p2) = −s2αβ
(B22(mA,mH) + B22(MZ ,mh)−M2
ZB0(MZ ,mh))
(B.16)
− c2αβ(B22(MZ ,mH) + B22(mA,mh)−M2
ZB0(MZ ,mh))
− 2 cos4 θW
(2p2 +M2
W −M2Z
sin4 θWcos2 θW
)B0(MW ,MW )
−(8 cos4 θW + cos2(2θW )
)B22(MW ,MW )
− cos2(2θW )B22(mH+ ,mH+)
−∑f
NC
∑s,t
∣∣∣∣∣I3∑i
W ∗fisWfit
−Qe sin2 θW δst
∣∣∣∣∣2
4B22(mfs,mft
)
+1
2
∑f
NC
∑s
((1− 8I3Qe sin2 θW )
∑i
W ∗fisWfis
+ 4Q2e sin4 θW
)A0(mfs
)
+∑f
NC
((g2fL + g2fR
)H(mf ,mf )− 4gfLgfRm
2fB0(mf ,mf )
)
– 38 –
JHEP07(2016)108
+cos2 θW
2g22
∑i,j
f0ijZH(mχ0i,mχ0
j) + 2g0ijZmχ0
imχ0
jB0(mχ0
i,mχ0
j)
+cos2 θWg22
∑i,j
f+ijZH(mχ+i,mχ+
j) + 2g+ijZmχ+
imχ+
jB0(mχ+
i,mχ+
j) .
The couplings f0Z , f+Z , g0Z , and g+Z are given in eqs. (A.7) and (D.5) of [59].
16π2ΠH+H−(p2) =∑Q
NC
((cos2 βy2u + sin2 βy2d
)G(mu,md)
− 2 sin(2β)yuydmumdB0(mu,md)
)+∑L
sin2 βy2eG(0,me)
+∑Q
NC
∑i,j
(λH+Q
)2ijB0(mui ,mdj
)
+∑L
∑i,j
(λH+L
)2ijB0(mνi ,mej )
+∑f
∑i
(λH+H−f
)iiA0(mfi
)
+g224
(s2αβF (mH ,MW ) + c2αβF (mh,MW ) + F (mA,MW )
+cos2(2θW )
cos2 θWF (mH+ ,MZ)
)+ e2F (mH+ , 0) + 2g22A0(MW ) + g22 cos2(2θW )A0(MZ)
+∑h+
(∑h0
(λH+h0h−)2B0(mh0 ,mh+) + λH+H−h+h−A0(mh+)
)
+ g22M2W
4B0(MW ,mA)
+1
2
∑h0
λH+H−h0h0A0(mh0)
+∑j,i
fijH+G(mχ+j,mχ0
i)− 2mχ+
jmχ0
igijH+B0(mχ+
j,mχ0
i) . (B.17)
The couplings fH+ and gH+ are given in eq. (D.70) and eqs. (D.39)–(D.42) of [59]. The
couplings λH+H−h− , λH+H−h+h− , and λH+H−h0h0 are defined in eqs. (D.63)–(D.65) and
eq. (D.67) of [59]. The couplings to sfermions in the case of inter-generational mixing are
given by
λH+Q = Wu
(g2√
2MW sin(2β) 13−
(y2u+y2
d
)cosβ v sin β√
2−T †d sinβ−µyd cosβ
−Tu cosβ − µ∗yu sinβ −yuyd v√2
)Wd , (B.18)
λH+L = Wν
(g2√
2MW sin(2β) 13 − y2
e cosβ v sin β√2
−T †e sinβ − µye cosβ)We , (B.19)
– 39 –
JHEP07(2016)108
λH+H−f = −W †f
− g222 cos(2β)(
cos(2θW )cos2 θW
I3 + tan2 θWQe
)13 0
0g222 cos(2β) tan2 θWQe 13
Wf
+
W †u
(y2d sin2 β 0
0 y2u cos2 β
)Wu f = u
W †d
(y2u cos2 β 0
0 y2d sin2 β
)Wd f = d
W †e
(0 0
0 y2e sin2 β
)We f = e
, (B.20)
λH+H−ν = −W †ν(−g
22
2cos(2β)
(cos(2θW )
cos2 θWI3 + tan2 θWQe
)13 − y2
e sin2 β
)Wν (B.21)
16π2ΠAA(p2) = cos2 β∑fu
NCy2fu
(p2B0(mfu ,mfu)− 2A0(mfu)
)+ sin2 β
∑fd
NCy2fd
(p2B0(mfd ,mfd)− 2A0(mfd)
)
+∑f
∑i
NC
(λAAf)iiA0(mfi
) +∑j
(λAf
)2
ijB0(mfi
,mfj)
+g2
2
4
(2F (mH+ ,MW ) +
s2αβ
cos2 θWF (mH ,MZ) +
c2αβcos2 θW
F (mh,MZ)
)
+1
2
∑h0n
∑h0m
λAh0nh
0mB0(mh0
n,mh0
m) + λAAh0
nh0nA0(mh0
n)
+ g2
2
(M2W
2B0(MW ,mHp) + 2A0(MW ) +
1
cos2 θWA0(MZ)
)+∑h+
λAAh+h+A0(mh+)
+1
2
∑i,j
f0ijAG(mχ0
i,mχ0
j)− 2g0
ijAmχ0imχ0
jB0(mχ0
i,mχ0
j)
+∑i,j
f+ijAG(mχ+
i,mχ+
j)− 2g+
ijAmχ+imχ+
jB0(mχ+
i,mχ+
j) . (B.22)
The couplings f0A, g0A, f+A , and g+A are given in eq. (D.70) and eqs. (D.34-D.38) of [59]. The
couplings λAh0h0 , λAAh0h0 , and λAAh+h+ are defined in eqs. (D.63-D.65) and eq. (D.67)
of [59]. The couplings to sfermions in the case of inter-generational mixing are given by
λAu = W †u
0 − 1√2
(T †u cosβ + µyu sinβ
)1√2
(Tu cosβ + µ∗yu sinβ
) Wu , (B.23)
λAe(d) = W †e(d)
0 − 1√2
(T †e(d) sinβ+µye(d) cosβ
)1√2
(Te(d) sinβ+µ∗ye(d) cosβ
) We(d) , (B.24)
λAν = 0 , (B.25)
– 40 –
JHEP07(2016)108
λAAf = W †f
− g222 cos(2β)(
1cos2 θW
I3 − tan2 θWQe
)13 0
0 − g22
2 cos(2β) tan2 θWQe 13
Wf
+
W †u
(y2u cos2 β 0
0 y2u cos2 β
)Wu f = u
W †d
(y2d sin2 β 0
0 y2d sin2 β
)Wd f = d
W †e
(y2e sin2 β 0
0 y2e sin2 β
)We f = e
, (B.26)
λAAν = −g22
2cos(2β)
(1
cos2 θWI3 − tan2 θWQe
)13 (B.27)
16π2td = −2∑fd
NCy2fdA0(mfd)
+∑f
NC∑i
g22
2MW cosβ
(λdf
)iiA0(mfi
)
− g22
cos(2β)
8 cos2 θW(A0(mA) + 2A0(mH+)) +
g22
2A0(mHp)
+g2
2
8 cos2 θW
(3 sin2 α− cos2 α+ sin(2α) tanβ
)A0(mh)
+g2
2
8 cos2 θW
(3 cos2 α− sin2 α− sin(2α) tanβ
)A0(mH)
− g22
∑i
mχ0i
MW cosβRe (Ni3(Ni2 −Ni,1 tan θW ))A0(mχ0
i)
−√
2g22
∑i
mχ+i
MW cosβRe (Vi1Ui2)A0(mχ+
i)
+3
4g2
2
(2A0(MW ) +
A0(MZ)
cos2 θW
)+ g2
2
cos(2β)
8 cos2 θW(2A0(MW ) +A0(MZ)) . (B.28)
The couplings to sfermion in the case of inter-generational mixing are given by
λdu = W †u
g2 MZcos θW
guL cosβ 13 −yu µ√2
−yu µ∗√2
g2MZ
cos θWguR cosβ 13
Wu , (B.29)
λdf = W †f
g2 MZcos θW
gfL cosβ 13 T †f1√2
Tf1√2
g2MZ
cos θWgfR cosβ 13
+
W †d
(Y 2d v cosβ 0
0 Y 2d v cosβ
)Wd f = d
W †e
(Y 2e v cosβ 0
0 Y 2e v cosβ
)We f = e
, (B.30)
– 41 –
JHEP07(2016)108
λdν = g2MZ
cos θWgνL cosβ 13 (B.31)
16π2tu = −2∑fu
NCy2fuA0(mfu)
+∑f
NC
∑i
g222MW sinβ
(λuf
)iiA0(mfi
)
+ g22cos(2β)
8 cos2 θW(A0(mA) + 2A0(mH+)) +
g222A0(mHp)
+g22
8 cos2 θW
(3 cos2 α− sin2 α+ sin(2α) cotβ
)A0(mh)
+g22
8 cos2 θW
(3 sin2 α− cos2 α− sin(2α) cotβ
)A0(mH)
− g22∑i
mχ0i
MW sinβRe (Ni4(Ni2 −Ni,1 tan θW ))A0(mχ0
i)
−√
2g22∑i
mχ+i
MW sinβRe (Vi2Ui1)A0(mχ+
i)
+3
4g22
(2A0(MW ) +
A0(MZ)
cos2 θW
)− g22
cos(2β)
8 cos2 θW(2A0(MW ) +A0(MZ)) . (B.32)
The couplings to sfermion in the case of inter-generational mixing are given by
λuu = W †u
(−g2
MZ
cos θWguL sinβ 13+y2
uv sinβ T †u1√2
Tu1√2
−g2MZ
cos θWguR sinβ 13+y2
uv sinβ
)Wu , (B.33)
λuf = W †f
(−g2
MZ
cos θWgfL sinβ 13 −yf µ√
2
−yf µ∗√
2−g2
MZ
cos θWgfR sinβ 13
)f = e , d ,
λuν = −g2MZ
cos θWgνL sinβ 13 . (B.34)
C SusyTC documentation
Here we present a documentation of the REAP extension SusyTC. To get started, please
follow first the steps described in section 4.
We now describe that additional features of SusyTC: in addition to the features of REAP
package RGEMSSMsoftbroken.m (described in the REAP documentation), SusyTC adds the
following options to the command RGEAdd:
• STCsignµ is the general factor eiφµ in front of µ in (3.36). (default: +1)
• STCcMSSM is a switch to change between the CP-violating (complex) MSSM and CP-
conserving (real) MSSM. (default: True)
– 42 –
JHEP07(2016)108
• STCSusyScale sets the SUSY scale Q (in GeV), where the MSSM is matched to the
SM. If set to "Automatic", SusyTC determines Q automatically from the sparticle
spectrum. (default: "Automatic")
• STCSusyScaleFromStops is a switch to choose whether SusyTC calculates the SUSY
scale Q as geometric mean of the stop masses Q =√mt1
mt2, where the stop masses
are defined by the up-type squark mass eigenstates ui with the largest mixing to t1 and
t2, or as geometric mean of the lightest and heaviest up-type squarks Q =√mu1mu6 .
Without effect if STCSusyScale is not set to "Automatic". (default: True)
• STCSearchSMTransition is a switch to enable or disable the matching to the SM
and the calculation of supersymmetric threshold corrections and sparticle spectrum.
(default: True)
• STCCCBConstraints is a switch to enable or disable a warning message for potentially
dangerous charge and colour breaking vacua, if large trilinear couplings violate the
constraints of [79] at the SUSY scale Q
|Tij |2 ≤(m2Rii +m2
Ljj +m2Hf
+ |µ|2)
(y2i + y2j ) i 6= j
3y2i i = j
, (C.1)
where mL, mR and mHf denote the soft-breaking mass parameters of the scalar fields
associated with the trilinear coupling T in the basis of diagonal Yukawa matrices.
(default: True)
• STCUFBConstraints is a switch to enable or disable a warning message for possibly
dangerous “unbounded from below” directions in the scalar potential, if the con-
straints of [69] are violated at the SUSY scale Q
m2Hu + |µ|2 +m2
Li− |m3|4m2Hd
+ |µ|2 −m2Li
> 0 UFB-2 , (C.2)
m2Hu +m2
Li> 0 UFB-3 , (C.3)
evaluated in the basis of (3.11). Note that the UFB-I constraint is automatically
satisfied, since SusyTC calculates m23 from m2
Hu, m2
Hd, MZ , and tan β by requiring
the existence of electroweak symmetry breaking. (default: True)
• STCTachyonConstraints is a switch to enable or disable the rejection of a parameter
point with tachyonic running masses of sfermions at any renormalization scale above
the SUSY scale Q. Regardless of this switch, tachyonic sfermion masses at Q are
always rejected. (default: False)
Thus, a typical call of RGEAdd[] might look like
RGEAdd["MSSMsoftbroken",RGEtanβ->20,STCcMSSM->False,STCsignµ->-1];
– 43 –
JHEP07(2016)108
In addition to the parameters known from the MSSM REAP model, the following soft-
breaking parameters are available as input for RGESetInitial:
• RGETu, RGETd, RGETe, and RGETν are the soft-breaking trilinear coupling matrices.
If given, the Constrained MSSM parameter RGEA0 for the corresponding trilinear
coupling is overwritten. (default: Constrained MSSM)
• RGEM1, RGEM2, and RGEM3 are the soft-breaking gaugino mass parameters. If given, the
Constrained MSSM parameter RGEM12 for the corresponding gaugino is overwritten.
(default: Constrained MSSM)
• RGEm2Q, RGEm2L, RGEm2u, RGEm2d, RGEm2e, RGEm2ν are the soft-breaking squared mass
matrices m2f
for the sfermions. If given, the Constrained MSSM parameter RGEm0 for
the corresponding scalar masses is overwritten. (default: Constrained MSSM)
• RGEm2Hd and RGEm2Hu are the soft-breaking squared masses for Hd and Hu, respec-
tively. If given, the Constrained MSSM parameter RGEm0 for the corresponding scalar
mass is overwritten. (default: Constrained MSSM)
• RGEM12 is the Constrained MSSM parameter for gaugino mass parameters in GeV.
(default: 750)
• RGEm0 is the Constrained MSSM parameter for all soft-breaking masses of scalars in
GeV. (default: 1500)
• RGEA0 is the Constrained MSSM parameter A0 for trilinear couplings, e.g. Tf = A0Yf .
(default: -500)
An example for an input at the GUT scale would be
RGESetInitial[2·10^16,RGEM1->863,RGEM2->131,
RGEM3->-392,RGESuggestion->"GUT"];
The solution at a lower energy scale such as MZ can now be obtained by the REAP
command RGESolve:
RGESolve[91.19,2·10^16];
Some parameter points might lead to tachyonic sparticle masses. In such instances the
evaluation of SusyTC is stopped and an error message is returned using the Mathematica
command Throw. In order to properly catch such error messages, we therefore recommend
to use instead
Catch[RGESolve[91.19,2·10^16],TachyonicMass];
In addition to the parameters known from the MSSM REAP model, the following soft-
breaking parameters are available for RGEGetSolution at all energy scales higher than the
SUSY scale Q:
– 44 –
JHEP07(2016)108
• RGETu, RGETd, RGETe, and RGETν are used to get the soft-breaking trilinear coupling
matrices.
• RawTν is used to get the raw (internal representation) of the soft-breaking trilinear
matrix for sneutrinos.
• RGEM1, RGEM2, and RGEM3 are used to get the soft-breaking gaugino mass parameters.
• RGEm2Q, RGEm2L, RGEm2u, RGEm2d, RGEm2e, RGEm2ν are used to get the soft-breaking
squared mass matrices m2f
for the sfermions.
• RGEm2Hd and RGEm2Hu are used to get the soft-breaking squared masses for Hd and
Hu, respectively.
To obtain the running DR gluino mass at a scale of two TeV for example, one uses
RGEGetSolution[2000,RGEM3];
With SusyTC the DR sparticle spectrum is automatically calculated. The following
functions are included in SusyTC:
• STCGetSUSYScale[] returns the SUSY scale Q.
• STCGetSUSYSpectrum[] returns a list of replacement rules for the SUSY scale Q,
the DR tree-level values of µ and m3, and the DR sparticle masses and (tree-level)
mixing matrices at the SUSY scale. In detail it contains
– "Q" the SUSY scale Q.
– "µ","m3" the values of µ and m3.
– "M1","M2","M3" are the gaugino mass parameters.
– "Mh","MH","MA","MHp" the (tree-level) masses of the MSSM Higgs bosons.11
– "mχ0" a list of the four neutralino masses.
– "mχp" a list of the two chargino masses.
– "msude" a 3×6 array of the six up-type quarks, down-type squarks and charged
slepton masses, respectively.
– "msν" a list of the three light sneutrino masses.
– "θW" the weak mixing angle.
– "tanα" the mixing angle of the CP-even Higgs bosons.
– "N" the mixing matrix of neutralinos.
– "U","V" the mixing matrices for charginos.
– "Wude" a list of the three sparticle mixing matrices for up-type squarks, down-
type squarks and charged sleptons.
11Note that there is no CP-violation in the MSSM Higgs sector on tree-level.
– 45 –
JHEP07(2016)108
– "Wν" the mixing matrix of the three light sneutrinos.
To obtain for example the SUSY scale and the tree-level masses of the charginos call
"Q"/.STCGetSUSYSpectrum[];
"mχp"/.STCGetSUSYSpectrum[];
The squark masses and charged slepton masses are contained in a joint list as
{mu,md,me}, and analogously for the sfermion mixing matrices. To obtain for
example the up-type squark masses, the charged slepton mixing matrix, and the
sneutrino masses type
("msude"/.STCGetSUSYSpectrum[])[[1]];
("Wude"/.STCGetSUSYSpectrum[])[[3]];
"msν"/.STCGetSUSYSpectrum[];
• STCGetOneLoopValues[] returns a list of replacement rules containing
– "µ","m3" the one-loop corrected DR µ-parameter andm3 as in (3.36) and (3.37)
at the SUSY scale Q.
– "vev" the one-loop DR vev v as in (3.41) at the SUSY scale Q.
– "MHp" ("MA") the pole-mass mH+ (mA) of the charged (CP-odd) Higgs boson
for STCcMSSM = True (False).
The value of µ can for example be obtained from
"µ"/.STCGetOneLoopValues[];
• STCGetSCKMValues[] returns a list of replacement rules with the soft-breaking mass
squared and trilinear coupling matrices in the SCKM basis, where sparticles are
rotated analogously with their corresponding superpartners.12 Since they are used for
the self-energies calculation as described in the previous appendix, they are returned
in SLHA2 convention [55]! In detail, there are
– "VCKM" the CKM mixing matrix.
– "VPMNS" the PMNS mixing matrix.
– SCKMBasis["m2Q"], SCKMBasis["m2u"], SCKMBasis["m2d"] the squark soft-
breaking mass squared matrices in the super CKM basis with SLHA2 convetions.
– SCKMBasis["m2L"], SCKMBasis["m2e"] the slepton soft-breaking mass
squared matrices in the super PMNS basis with SLHA2 conventions.
– SCKMBasis["T"] a list of the three trilinear coupling matrices for up-type
squarks, down-type squarks and charged sleptons in the SCKM basis with
SLHA2 conventions.12We use the term “SCKM” for the super CKM and super PMNS basis.
– 46 –
JHEP07(2016)108
– SCKMBasis["Y"] a 3×3 array of the Yukawa coupling singular values for up-type
squarks, down-type squarks and charged sleptons.
To obtain the down-type trilinear coupling matrix and the mass squared matrix of
the left-handed up-type squarks in the SLHA basis for example, type
(SCKMBasis["T"]/.STCGetSCKMValues[])[[2]];
SCKMBasis["mQ2u"]/.STCGetSCKMValues[];
• STCGetInternalValues[] returns everything that is internally used for the cal-
culation of the threshold corrections and sparticle spectrum, i.e. the results from
STCGetSCKMValues[] and STCGetSUSYSpectrum[] with the one-loop corrected pa-
rameters from STCGetOneLoopValues[] replacing tree-level ones if available. We
recommend to the user to use those separate functions instead.
As additional feature, SusyTC optionally supports input and output as SLHA “Les
Houches” files. These files follow SLHA conventions [55, 58]:
• STCSLHA2Input[“Path”] loads an “Les Houches” input file stored in “Path” and
executes REAP and SusyTC. If no path is given, the default path is assumed as
“SusyTC.in” in the Mathematica Notebook Directory. An important difference to
other spectrum calculators is the pure “top-down” approach by SusyTC, i.e. there
is no attempt of fitting SM inputs at a low scale or calculating a GUT-scale from
gauge couplings unification. Instead, all input is given at a user-defined high energy
scale, which is then evolved to lower scales. The input should be given in the flavour
basis in SLHA 2 convention [55], with analogous convention for Yν and convention
for Mn as in (3.1). The relation between the SusyTC conventions and the SLHA 2
conventions is given in section 3. In the following, we list all SLHA 2 input blocks,
which are available in SusyTC:
– Block MODSEL: the only available switch is:
5 : (Default = 2) CP violation (STCcMSSM)
– Block SusyTCInput: Switches (1=True, 0=False) are defined for RGEAdd[]:
1 : (Default = 1) STCSusyScaleFromStops
2 : (Default = 1) STCSearchSMTransition
3 : (Default = 1) STCCCBConstraints
4 : (Default = 1) STCUFBConstraints
5 : (Default = 1) Print a Warning in case of Tachyonic masses
6 : (Default = 1) One or Two Loop RGEs
– Block MINPAR: Constrained MSSM parameters as defined in [55, 58]. Note
however, that the input value of tan β is interpreted to be given at the SUSY
scale.
– Block IMMINPAR: reads the sinφµ in case of the complex MSSM:
4 : sinφµ
– 47 –
JHEP07(2016)108
– Block EXTPAR:
0 : (Default = 2 · 1016): Minput Input scale
Note that with SusyTC an automatic calculation of the GUT scale is not possible.
The remainder of the block works as usual, e.g. optionally one can overwrite
common Constrained MSSM gaugino or Higgs soft-breaking parameters:
1 : M1(Minput) bino mass (real part)
2 : M2(Minput) wino mass (real part)
3 : M3(Minput) gluino mass (real part)
21 : m2Hd
(Minput)
22 : m2Hu
(Minput)
Imaginary components for the gaugino masses can be given in Block IMEXTPAR.
– Block IMEXTPAR: as defined in [55].
– Block QEXTPAR: low energy input:
0 : (Default = 91.1876): the low energy scale to which REAP evolves the SM
RGEs.
23 : “SUSY scale” Q, where the MSSM is matched to the SM. If this entry is
set, it overwrites the automatically calculated SUSY scale.
– Block GAUGE: the DR gauge couplings at the input scale
1 : g1(Minput) U(1) gauge coupling
2 : g2(Minput) SU(2) gauge coupling
3 : g3(Minput) SU(3) gauge coupling
– Block YU, Block YD, Block YE, Block YN: the real parts of the Yukawa ma-
trices Yu, Yd, Ye, and Yν in the flavour basis [55]. They should be given in
the FORTRAN format (1x,I2,1x,I2,3x,1P,E16.8,0P,3x,‘#’,1x,A), where the
first two integers correspond to the indices and the double precision number to
Re(Yij).
– Block IMYU, Block IMYD, Block IMYE, Block IMYN: the imaginary parts of
the Yukawa matrices Yu, Yd, Ye, and Yν in the flavour basis [55]. They are given
in the same format as the real parts.
– Block MN: the real part of the symmetric Majorana mass matrix Mn of the right-
handed neutrinos in the flavour basis (3.1). Only the “upper-triangle” entries
should be given, the input format is as for the Yukawa matrices.
– Block IMMN: the imaginary part of the symmetric Majorana mass matrix Mn of
the right-handed neutrinos in the flavour basis (3.1). Only the “upper-triangle”
entries should be given, the input format is as for the Yukawa matrices.
The remaining blocks can be given optionally to overwrite Constrained MSSM input
boundary conditions:
– Block TU, Block TD, Block TE, Block TN: the real parts of the trilinear
soft-breaking matrices Tu, Td, Te, and Tν in the flavour basis [55]. They should
be given in the same format as the Yukawa matrices.
– 48 –
JHEP07(2016)108
– Block IMTU, Block IMTD, Block IMTE, Block IMTN: the imaginary parts of
the trilinear soft-breaking matrices Tu, Td, Te, and Tν in the flavour basis [55].
They should be given in the same format as the Yukawa matrices.
– Block MSQ2, Block MSU2, Block MSD2, Block MSL2, Block MSE2,
Block MSN2: the real parts of the soft-breaking mass squared matrices m2Q
, m2u,
m2d, m2
L, m2
e, and m2ν in the flavour basis [55]. Only the “upper-triangle” entries
should be given, the input format is as for the Yukawa matrices.
– Block IMMSQ2, Block IMMSU2, Block IMMSD2,Block IMMSL2,
Block IMMSE2, Block IMMSN2: the imaginary parts of the soft-breaking mass
squared matrices m2Q
, m2u, m2
d, m2
L, m2
e, and m2ν in the flavour basis [55]. Only
the “upper-triangle” entries should be given, the input format is as for the
Yukawa matrices.
• STCWriteSLHA2Output[“Path”] writes an “Les Houches” [55, 58] output file to
“Path”. If no path is given, the output is saved in the Mathematica Notebook di-
rectory as “SusyTC.out”. The output follows SLHA conventions, with the following
exceptions:
– Block MASS: the mass spectrum is given as DR masses at the SUSY scale. The
only exception is the pole mass MH+ (MA) for CP violation turned on (off).
– Block ALPHA: the tree-level Higgs mixing angle αtree.
– Block HMIX: instead of MA we give
101 : m3
The other blocks follow the SLHA2 output conventions, e.g. DR values at the
SUSY scale in the Super-CKM/Super-PMNS basis. To avoid confusion, the
blocks Block DSQMIX, Block USQMIX, Block SELMIX, Block SNUMIX and the cor-
responding blocks for the imaginary entries, return the sfermion mixing matrices Rfin SLHA 2 convention.
Open Access. This article is distributed under the terms of the Creative Commons
Attribution License (CC-BY 4.0), which permits any use, distribution and reproduction in
any medium, provided the original author(s) and source are credited.
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